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Creative Problem Solving

Finding innovative solutions to challenges.

By the Mind Tools Content Team

Imagine that you're vacuuming your house in a hurry because you've got friends coming over. Frustratingly, you're working hard but you're not getting very far. You kneel down, open up the vacuum cleaner, and pull out the bag. In a cloud of dust, you realize that it's full... again. Coughing, you empty it and wonder why vacuum cleaners with bags still exist!

James Dyson, inventor and founder of Dyson® vacuum cleaners, had exactly the same problem, and he used creative problem solving to find the answer. While many companies focused on developing a better vacuum cleaner filter, he realized that he had to think differently and find a more creative solution. So, he devised a revolutionary way to separate the dirt from the air, and invented the world's first bagless vacuum cleaner. [1]

Creative problem solving (CPS) is a way of solving problems or identifying opportunities when conventional thinking has failed. It encourages you to find fresh perspectives and come up with innovative solutions, so that you can formulate a plan to overcome obstacles and reach your goals.

In this article, we'll explore what CPS is, and we'll look at its key principles. We'll also provide a model that you can use to generate creative solutions.

About Creative Problem Solving

Alex Osborn, founder of the Creative Education Foundation, first developed creative problem solving in the 1940s, along with the term "brainstorming." And, together with Sid Parnes, he developed the Osborn-Parnes Creative Problem Solving Process. Despite its age, this model remains a valuable approach to problem solving. [2]

The early Osborn-Parnes model inspired a number of other tools. One of these is the 2011 CPS Learner's Model, also from the Creative Education Foundation, developed by Dr Gerard J. Puccio, Marie Mance, and co-workers. In this article, we'll use this modern four-step model to explore how you can use CPS to generate innovative, effective solutions.

Why Use Creative Problem Solving?

Dealing with obstacles and challenges is a regular part of working life, and overcoming them isn't always easy. To improve your products, services, communications, and interpersonal skills, and for you and your organization to excel, you need to encourage creative thinking and find innovative solutions that work.

CPS asks you to separate your "divergent" and "convergent" thinking as a way to do this. Divergent thinking is the process of generating lots of potential solutions and possibilities, otherwise known as brainstorming. And convergent thinking involves evaluating those options and choosing the most promising one. Often, we use a combination of the two to develop new ideas or solutions. However, using them simultaneously can result in unbalanced or biased decisions, and can stifle idea generation.

For more on divergent and convergent thinking, and for a useful diagram, see the book "Facilitator's Guide to Participatory Decision-Making." [3]

Core Principles of Creative Problem Solving

CPS has four core principles. Let's explore each one in more detail:

Divergent and convergent thinking must be balanced. The key to creativity is learning how to identify and balance divergent and convergent thinking (done separately), and knowing when to practice each one.
Ask problems as questions. When you rephrase problems and challenges as open-ended questions with multiple possibilities, it's easier to come up with solutions. Asking these types of questions generates lots of rich information, while asking closed questions tends to elicit short answers, such as confirmations or disagreements. Problem statements tend to generate limited responses, or none at all.
Defer or suspend judgment. As Alex Osborn learned from his work on brainstorming, judging solutions early on tends to shut down idea generation. Instead, there's an appropriate and necessary time to judge ideas during the convergence stage.
Focus on "Yes, and," rather than "No, but." Language matters when you're generating information and ideas. "Yes, and" encourages people to expand their thoughts, which is necessary during certain stages of CPS. Using the word "but" – preceded by "yes" or "no" – ends conversation, and often negates what's come before it.

How to Use the Tool

Let's explore how you can use each of the four steps of the CPS Learner's Model (shown in figure 1, below) to generate innovative ideas and solutions.

Figure 1 – CPS Learner's Model

Explore the Vision

Identify your goal, desire or challenge. This is a crucial first step because it's easy to assume, incorrectly, that you know what the problem is. However, you may have missed something or have failed to understand the issue fully, and defining your objective can provide clarity. Read our article, 5 Whys , for more on getting to the root of a problem quickly.

Gather Data

Once you've identified and understood the problem, you can collect information about it and develop a clear understanding of it. Make a note of details such as who and what is involved, all the relevant facts, and everyone's feelings and opinions.

Formulate Questions

When you've increased your awareness of the challenge or problem you've identified, ask questions that will generate solutions. Think about the obstacles you might face and the opportunities they could present.

Explore Ideas

Generate ideas that answer the challenge questions you identified in step 1. It can be tempting to consider solutions that you've tried before, as our minds tend to return to habitual thinking patterns that stop us from producing new ideas. However, this is a chance to use your creativity .

Brainstorming and Mind Maps are great ways to explore ideas during this divergent stage of CPS. And our articles, Encouraging Team Creativity , Problem Solving , Rolestorming , Hurson's Productive Thinking Model , and The Four-Step Innovation Process , can also help boost your creativity.

See our Brainstorming resources within our Creativity section for more on this.

Formulate Solutions

This is the convergent stage of CPS, where you begin to focus on evaluating all of your possible options and come up with solutions. Analyze whether potential solutions meet your needs and criteria, and decide whether you can implement them successfully. Next, consider how you can strengthen them and determine which ones are the best "fit." Our articles, Critical Thinking and ORAPAPA , are useful here.

4. Implement

Formulate a plan.

Once you've chosen the best solution, it's time to develop a plan of action. Start by identifying resources and actions that will allow you to implement your chosen solution. Next, communicate your plan and make sure that everyone involved understands and accepts it.

There have been many adaptations of CPS since its inception, because nobody owns the idea.

For example, Scott Isaksen and Donald Treffinger formed The Creative Problem Solving Group Inc . and the Center for Creative Learning , and their model has evolved over many versions. Blair Miller, Jonathan Vehar and Roger L. Firestien also created their own version, and Dr Gerard J. Puccio, Mary C. Murdock, and Marie Mance developed CPS: The Thinking Skills Model. [4] Tim Hurson created The Productive Thinking Model , and Paul Reali developed CPS: Competencies Model. [5]

Sid Parnes continued to adapt the CPS model by adding concepts such as imagery and visualization , and he founded the Creative Studies Project to teach CPS. For more information on the evolution and development of the CPS process, see Creative Problem Solving Version 6.1 by Donald J. Treffinger, Scott G. Isaksen, and K. Brian Dorval. [6]

Creative Problem Solving (CPS) Infographic

See our infographic on Creative Problem Solving .

Creative problem solving (CPS) is a way of using your creativity to develop new ideas and solutions to problems. The process is based on separating divergent and convergent thinking styles, so that you can focus your mind on creating at the first stage, and then evaluating at the second stage.

There have been many adaptations of the original Osborn-Parnes model, but they all involve a clear structure of identifying the problem, generating new ideas, evaluating the options, and then formulating a plan for successful implementation.

[1] Entrepreneur (2012). James Dyson on Using Failure to Drive Success [online]. Available here . [Accessed May 27, 2022.]

[2] Creative Education Foundation (2015). The CPS Process [online]. Available here . [Accessed May 26, 2022.]

[3] Kaner, S. et al. (2014). 'Facilitator′s Guide to Participatory Decision–Making,' San Francisco: Jossey-Bass.

[4] Puccio, G., Mance, M., and Murdock, M. (2011). 'Creative Leadership: Skils That Drive Change' (2nd Ed.), Thousand Oaks, CA: Sage.

[5] OmniSkills (2013). Creative Problem Solving [online]. Available here . [Accessed May 26, 2022].

[6] Treffinger, G., Isaksen, S., and Dorval, B. (2010). Creative Problem Solving (CPS Version 6.1). Center for Creative Learning, Inc. & Creative Problem Solving Group, Inc. Available here .

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The Palgrave Encyclopedia of the Possible pp 298–313 Cite as

Creative Problem-Solving
Gerard J. Puccio 2 ,
Barry Klarman 2 &
Pamela A. Szalay 2
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Life and work in the beginning of the twenty-first century has been described as volatile, uncertain, complex, and ambiguous. In this fast changing, innovation-driven environment, Creative Problem-Solving has been identified as a fundamental skill for success. In contrast to routine problem-solving, with straightforward and repeatable solution paths, today’s problems are described as being complex and wicked. To generate the possibilities that can effectively address complex problems, individuals need to draw on the highest level of human thought – creativity. Creative Problem-Solving explicitly draws on, and promotes, effective creative thinking. The purpose of this entry is to describe and distinguish Creative Problem-Solving from other forms of problems-solving. Moreover, as Creative Problem-Solving is a deliberate creativity methodology, this chapter also provides a description of the more specific thinking skills that are embodied by the higher-order skill of creative thinking and are explicitly called on in Creative Problem-Solving. Complex problems require complex thinking, and Creative Problem-Solving provides a structured process that allows individuals to more easily and efficiently deploy their creative thinking skills.

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Anderson, L. W., & Krathwohl, D. R. (Eds.). (2001). A taxonomy for learning, teaching and assessing: A revision of Bloom’s taxonomy of educational objectives: Complete edition . New York: Longman.

Google Scholar

Basadur, M. (1994). Simplex. Buffalo, NY: The Creative Education Foundation.

Brackett, M. (2019). Permission to feel: Unlocking the power of emotions to help our kids, ourselves, and our society thrive . New York: Celadon Books.

Csikszentmihalyi, M. (1990). Flow: The psychology of optimal experience . New York: HarperPerennial.

Csikszentmihalyi, M. (1996). Creativity: Flow and the psychology of discovery and invention . New York: HarperCollins.

Darwin, C. (2003). The origin of species: By means of natural selection of the preservation of favoured races in the struggle for life (p. 252). New York: Signet Classics.

Goleman, D. (1995). Emotional intelligence: Why it can matter more than IQ . New York: Bantam.

Isaksen, S. G., & Treffinger, D. J. (1985). Creative problem solving: The basic course. Buffalo, NY: Bearly Limited.

Isaksen, S. G., Dorval, K. B., & Treffinger, D. J. (1994). Creative approaches to problem solving. Dubuque, IA: Kendall/Hunt.

Isaksen, S. G., Dorval, K. B. & Treffinger, D. J. (2000). Creative approaches to problem solving (2nd ed.). Dubuque, IA: Kendall/Hunt Publishing.

Johnson, B. (1996). Polarity management: Identifying and managing unsolvable problem . Amherst: HRD Press.

Miller, J. C. (2004). The transcendent function: Jung’s model of psychological growth through dialogue with the unconscious . Albany: State University of New York Press.

Morriss-Kay, G. M. (2010). The evolution of human artistic creativity. Journal of Anatomy, 216 , 158–176.

Article Google Scholar

Mumford, M. D., Zaccaro, S. J., Harding, F. D., Jacobs, T. O., & Fleishman, E. A. (2000). Leadership skills for a changing world: Solving complex problems. Leadership Quarterly, 11 , 11–35.

Osborn, A. F. (1953). Applied imagination: Principles and procedures of creative problem-solving . New York: Scribner.

Osborn, A. F. (1963). Applied imagination: Principles and procedures of creative problem-solving (3rd ed.). New York: Scribner.

Otani, A. (2015, January). These are the skills you need if you want to be headhunted. Retrieved on 27 July 2015 from Osborn, A. F. (1953). Applied imagination: Principles and procedures of creative problem-solving . New York: Scribner.

Parnes, S. J. (1967). Creative behavior workbook. New York: Charles Scribner’s Sons.

Parnes, S. J. (1988). Visionizing. East Aurora, NY: D.O.K. Publishers.

Parnes, S. J. (1992). Creative problem solving and visionizing. In S.J. Parnes (Ed.), Sourcebook for creative problem solving (pp. 133–154). Buffalo, NY: Creative Education Press.

Parnes, S. J., & Biondi, A. M. (1975). Creative behavior: A delicate balance. The Journal of Creative Behavior, 9 , 149–158.

Puccio, G. J. (2017). From the dawn of humanity to the 21st century: Creativity as an enduring survival skill. The Journal of Creative Behavior, 51 , 330–334. https://doi.org/10.1002/jocb.203 .

Puccio, G. J., Murdock, M. C., & Mance, M. (2005). Current developments in creative problem solving for organizations: A focus on thinking skills and styles. The Korean Journal of Thinking & Problem Solving, 15 , 43–76.

Puccio, G. J., Mance, M., & Murdock, M. (2011). Creative leadership: Skills that drive change (2nd ed.). Thousand Oaks: SAGE.

Puccio, G. J., Mance, M., Switalski, B., & Reali, P. (2012). Creativity rising: Creative thinking and problem solving in the 21st century . Buffalo: ICSC Press.

Puccio, G. J., Burnett, C., Acar, S., Yudess, J. A., Holinger, M., & Cabra, J. F. (2018). Creative problem solving in small groups: The effects of creativity training on idea generation, solution creativity, and leadership effectiveness. The Journal of Creative Behavior . Advance online publication. [not sure of order]. https://doi.org/10.1002/jocb.381 .

Scott, G. M., Leritz, L. E., & Mumford, M. D. (2004). The effectiveness of creativity training: A meta-analysis. Creativity Research Journal, 16 , 361–388.

Stokes, P. D. (2013). Crossing disciplines: A constraint-based model of the creative/innovative process. The Journal of Product Innovation Management, 31 (2), 247–228. https://doi.org/10.1111/jpim.12093 .

Trilling, B., & Fadel, C. (2009). 21st century skills: Learning for life in our times . San Francisco: Jossey-Bass.

Vehar, J. R., Firestien, R. L., & Miller, B. (1997). Creativity unbound. Williamsville, NY: Innovation Systems Group.

Wagner, T. (2008). The global achievement gap: Why even our best schools don’t teach the new survival skills our children need – And what we can do about it . New York: Basic Books.

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Teaching Creativity and Inventive Problem Solving in Science

Robert L. DeHaan

Division of Educational Studies, Emory University, Atlanta, GA 30322

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Engaging learners in the excitement of science, helping them discover the value of evidence-based reasoning and higher-order cognitive skills, and teaching them to become creative problem solvers have long been goals of science education reformers. But the means to achieve these goals, especially methods to promote creative thinking in scientific problem solving, have not become widely known or used. In this essay, I review the evidence that creativity is not a single hard-to-measure property. The creative process can be explained by reference to increasingly well-understood cognitive skills such as cognitive flexibility and inhibitory control that are widely distributed in the population. I explore the relationship between creativity and the higher-order cognitive skills, review assessment methods, and describe several instructional strategies for enhancing creative problem solving in the college classroom. Evidence suggests that instruction to support the development of creativity requires inquiry-based teaching that includes explicit strategies to promote cognitive flexibility. Students need to be repeatedly reminded and shown how to be creative, to integrate material across subject areas, to question their own assumptions, and to imagine other viewpoints and possibilities. Further research is required to determine whether college students' learning will be enhanced by these measures.

INTRODUCTION

Dr. Dunne paces in front of his section of first-year college students, today not as their Bio 110 teacher but in the role of facilitator in their monthly “invention session.” For this meeting, the topic is stem cell therapy in heart disease. Members of each team of four students have primed themselves on the topic by reading selected articles from accessible sources such as Science, Nature, and Scientific American, and searching the World Wide Web, triangulating for up-to-date, accurate, background information. Each team knows that their first goal is to define a set of problems or limitations to overcome within the topic and to begin to think of possible solutions. Dr. Dunne starts the conversation by reminding the group of the few ground rules: one speaker at a time, listen carefully and have respect for others' ideas, question your own and others' assumptions, focus on alternative paths or solutions, maintain an atmosphere of collaboration and mutual support. He then sparks the discussion by asking one of the teams to describe a problem in need of solution.

Science in the United States is widely credited as a major source of discovery and economic development. According to the 2005 TAP Report produced by a prominent group of corporate leaders, “To maintain our country's competitiveness in the twenty-first century, we must cultivate the skilled scientists and engineers needed to create tomorrow's innovations.” ( www.tap2015.org/about/TAP_report2.pdf ). A panel of scientists, engineers, educators, and policy makers convened by the National Research Council (NRC) concurred with this view, reporting that the vitality of the nation “is derived in large part from the productivity of well-trained people and the steady stream of scientific and technical innovations they produce” ( NRC, 2007 ).

For many decades, science education reformers have promoted the idea that learners should be engaged in the excitement of science; they should be helped to discover the value of evidence-based reasoning and higher-order cognitive skills, and be taught to become innovative problem solvers (for reviews, see DeHaan, 2005 ; Hake, 2005 ; Nelson, 2008 ; Perkins and Wieman, 2008 ). But the means to achieve these goals, especially methods to promote creative thinking in scientific problem solving, are not widely known or used. An invention session such as that led by the fictional Dr. Dunne, described above, may seem fanciful as a means of teaching students to think about science as something more than a body of facts and terms to memorize. In recent years, however, models for promoting creative problem solving were developed for classroom use, as detailed by Treffinger and Isaksen (2005) , and such techniques are often used in the real world of high technology. To promote imaginative thinking, the advertising executive Alex F. Osborn invented brainstorming ( Osborn, 1948 , 1979 ), a technique that has since been successful in stimulating inventiveness among engineers and scientists. Could such strategies be transferred to a class for college students? Could they serve as a supplement to a high-quality, scientific teaching curriculum that helps students learn the facts and conceptual frameworks of science and make progress along the novice–expert continuum? Could brainstorming or other instructional strategies that are specifically designed to promote creativity teach students to be more adaptive in their growing expertise, more innovative in their problem-solving abilities? To begin to answer those questions, we first need to understand what is meant by “creativity.”

What Is Creativity? Big-C versus Mini-C Creativity

How to define creativity is an age-old question. Justice Potter Stewart's famous dictum regarding obscenity “I know it when I see it” has also long been an accepted test of creativity. But this is not an adequate criterion for developing an instructional approach. A scientist colleague of mine recently noted that “Many of us [in the scientific community] rarely give the creative process a second thought, imagining one either ‘has it’ or doesn't.” We often think of inventiveness or creativity in scientific fields as the kind of gift associated with a Michelangelo or Einstein. This is what Kaufman and Beghetto (2008) call big-C creativity, borrowing the term that earlier workers applied to the talents of experts in various fields who were identified as particularly creative by their expert colleagues ( MacKinnon, 1978 ). In this sense, creativity is seen as the ability of individuals to generate new ideas that contribute substantially to an intellectual domain. Howard Gardner defined such a creative person as one who “regularly solves problems, fashions products, or defines new questions in a domain in a way that is initially considered novel but that ultimately comes to be accepted in a particular cultural setting” ( Gardner, 1993 , p. 35).

But there is another level of inventiveness termed by various authors as “little-c” ( Craft, 2000 ) or “mini-c” ( Kaufman and Beghetto, 2008 ) creativity that is widespread among all populations. This would be consistent with the workplace definition of creativity offered by Amabile and her coworkers: “coming up with fresh ideas for changing products, services and processes so as to better achieve the organization's goals” ( Amabile et al. , 2005 ). Mini-c creativity is based on what Craft calls “possibility thinking” ( Craft, 2000 , pp. 3–4), as experienced when a worker suddenly has the insight to visualize a new, improved way to accomplish a task; it is represented by the “aha” moment when a student first sees two previously disparate concepts or facts in a new relationship, an example of what Arthur Koestler identified as bisociation: “perceiving a situation or event in two habitually incompatible associative contexts” ( Koestler, 1964 , p. 95).

In this essay, I maintain that mini-c creativity is not a mysterious, innate endowment of rare individuals. Instead, I argue that creative thinking is a multicomponent process, mediated through social interactions, that can be explained by reference to increasingly well-understood mental abilities such as cognitive flexibility and cognitive control that are widely distributed in the population. Moreover, I explore some of the recent research evidence (though with no effort at a comprehensive literature review) showing that these mental abilities are teachable; like other higher-order cognitive skills (HOCS), they can be enhanced by explicit instruction.

Creativity Is a Multicomponent Process

Efforts to define creativity in psychological terms go back to J. P. Guilford ( Guilford, 1950 ) and E. P. Torrance ( Torrance, 1974 ), both of whom recognized that underlying the construct were other cognitive variables such as ideational fluency, originality of ideas, and sensitivity to missing elements. Many authors since then have extended the argument that a creative act is not a singular event but a process, an interplay among several interactive cognitive and affective elements. In this view, the creative act has two phases, a generative and an exploratory or evaluative phase ( Finke et al. , 1996 ). During the generative process, the creative mind pictures a set of novel mental models as potential solutions to a problem. In the exploratory phase, we evaluate the multiple options and select the best one. Early scholars of creativity, such as J. P. Guilford, characterized the two phases as divergent thinking and convergent thinking ( Guilford, 1950 ). Guilford defined divergent thinking as the ability to produce a broad range of associations to a given stimulus or to arrive at many solutions to a problem (for overviews of the field from different perspectives, see Amabile, 1996 ; Banaji et al. , 2006 ; Sawyer, 2006 ). In neurocognitive terms, divergent thinking is referred to as associative richness ( Gabora, 2002 ; Simonton, 2004 ), which is often measured experimentally by comparing the number of words that an individual generates from memory in response to stimulus words on a word association test. In contrast, convergent thinking refers to the capacity to quickly focus on the one best solution to a problem.

The idea that there are two stages to the creative process is consistent with results from cognition research indicating that there are two distinct modes of thought, associative and analytical ( Neisser, 1963 ; Sloman, 1996 ). In the associative mode, thinking is defocused, suggestive, and intuitive, revealing remote or subtle connections between items that may be correlated, or may not, and are usually not causally related ( Burton, 2008 ). In the analytical mode, thought is focused and evaluative, more conducive to analyzing relationships of cause and effect (for a review of other cognitive aspects of creativity, see Runco, 2004 ). Science educators associate the analytical mode with the upper levels (analysis, synthesis, and evaluation) of Bloom's taxonomy (e.g., Crowe et al. , 2008 ), or with “critical thinking,” the process that underlies the “purposeful, self-regulatory judgment that drives problem-solving and decision-making” ( Quitadamo et al. , 2008 , p. 328). These modes of thinking are under cognitive control through the executive functions of the brain. The core executive functions, which are thought to underlie all planning, problem solving, and reasoning, are defined ( Blair and Razza, 2007 ) as working memory control (mentally holding and retrieving information), cognitive flexibility (considering multiple ideas and seeing different perspectives), and inhibitory control (resisting several thoughts or actions to focus on one). Readers wishing to delve further into the neuroscience of the creative process can refer to the cerebrocerebellar theory of creativity ( Vandervert et al. , 2007 ) in which these mental activities are described neurophysiologically as arising through interactions among different parts of the brain.

The main point from all of these works is that creativity is not some single hard-to-measure property or act. There is ample evidence that the creative process requires both divergent and convergent thinking and that it can be explained by reference to increasingly well-understood underlying mental abilities ( Haring-Smith, 2006 ; Kim, 2006 ; Sawyer, 2006 ; Kaufman and Sternberg, 2007 ) and cognitive processes ( Simonton, 2004 ; Diamond et al. , 2007 ; Vandervert et al. , 2007 ).

Creativity Is Widely Distributed and Occurs in a Social Context

Although it is understandable to speak of an aha moment as a creative act by the person who experiences it, authorities in the field have long recognized (e.g., Simonton, 1975 ) that creative thinking is not so much an individual trait but rather a social phenomenon involving interactions among people within their specific group or cultural settings. “Creativity isn't just a property of individuals, it is also a property of social groups” ( Sawyer, 2006 , p. 305). Indeed, Osborn introduced his brainstorming method because he was convinced that group creativity is always superior to individual creativity. He drew evidence for this conclusion from activities that demand collaborative output, for example, the improvisations of a jazz ensemble. Although each musician is individually creative during a performance, the novelty and inventiveness of each performer's playing is clearly influenced, and often enhanced, by “social and interactional processes” among the musicians ( Sawyer, 2006 , p. 120). Recently, Brophy (2006) offered evidence that for problem solving, the situation may be more nuanced. He confirmed that groups of interacting individuals were better at solving complex, multipart problems than single individuals. However, when dealing with certain kinds of single-issue problems, individual problem solvers produced a greater number of solutions than interacting groups, and those solutions were judged to be more original and useful.

Consistent with the findings of Brophy (2006) , many scholars acknowledge that creative discoveries in the real world such as solving the problems of cutting-edge science—which are usually complex and multipart—are influenced or even stimulated by social interaction among experts. The common image of the lone scientist in the laboratory experiencing a flash of creative inspiration is probably a myth from earlier days. As a case in point, the science historian Mara Beller analyzed the social processes that underlay some of the major discoveries of early twentieth-century quantum physics. Close examination of successive drafts of publications by members of the Copenhagen group revealed a remarkable degree of influence and collaboration among 10 or more colleagues, although many of these papers were published under the name of a single author ( Beller, 1999 ). Sociologists Bruno Latour and Steve Woolgar's study ( Latour and Woolgar, 1986 ) of a neuroendocrinology laboratory at the Salk Institute for Biological Studies make the related point that social interactions among the participating scientists determined to a remarkable degree what discoveries were made and how they were interpreted. In the laboratory, researchers studied the chemical structure of substances released by the brain. By analysis of the Salk scientists' verbalizations of concepts, theories, formulas, and results of their investigations, Latour and Woolgar showed that the structures and interpretations that were agreed upon, that is, the discoveries announced by the laboratory, were mediated by social interactions and power relationships among members of the laboratory group. By studying the discovery process in other fields of the natural sciences, sociologists and anthropologists have provided more cases that further illustrate how social and cultural dimensions affect scientific insights (for a thoughtful review, see Knorr Cetina, 1995 ).

In sum, when an individual experiences an aha moment that feels like a singular creative act, it may rather have resulted from a multicomponent process, under the influence of group interactions and social context. The process that led up to what may be sensed as a sudden insight will probably have included at least three diverse, but testable elements: 1) divergent thinking, including ideational fluency or cognitive flexibility, which is the cognitive executive function that underlies the ability to visualize and accept many ideas related to a problem; 2) convergent thinking or the application of inhibitory control to focus and mentally evaluate ideas; and 3) analogical thinking, the ability to understand a novel idea in terms of one that is already familiar.

LITERATURE REVIEW

What do we know about how to teach creativity.

The possibility of teaching for creative problem solving gained credence in the 1960s with the studies of Jerome Bruner, who argued that children should be encouraged to “treat a task as a problem for which one invents an answer, rather than finding one out there in a book or on the blackboard” ( Bruner, 1965 , pp. 1013–1014). Since that time, educators and psychologists have devised programs of instruction designed to promote creativity and inventiveness in virtually every student population: pre–K, elementary, high school, and college, as well as in disadvantaged students, athletes, and students in a variety of specific disciplines (for review, see Scott et al. , 2004 ). Smith (1998) identified 172 instructional approaches that have been applied at one time or another to develop divergent thinking skills.

Some of the most convincing evidence that elements of creativity can be enhanced by instruction comes from work with young children. Bodrova and Leong (2001) developed the Tools of the Mind (Tools) curriculum to improve all of the three core mental executive functions involved in creative problem solving: cognitive flexibility, working memory, and inhibitory control. In a year-long randomized study of 5-yr-olds from low-income families in 21 preschool classrooms, half of the teachers applied the districts' balanced literacy curriculum (literacy), whereas the experimenters trained the other half to teach the same academic content by using the Tools curriculum ( Diamond et al. , 2007 ). At the end of the year, when the children were tested with a battery of neurocognitive tests including a test for cognitive flexibility ( Durston et al. , 2003 ; Davidson et al. , 2006 ), those exposed to the Tools curriculum outperformed the literacy children by as much as 25% ( Diamond et al. , 2007 ). Although the Tools curriculum and literacy program were similar in academic content and in many other ways, they differed primarily in that Tools teachers spent 80% of their time explicitly reminding the children to think of alternative ways to solve a problem and building their executive function skills.

Teaching older students to be innovative also demands instruction that explicitly promotes creativity but is rigorously content-rich as well. A large body of research on the differences between novice and expert cognition indicates that creative thinking requires at least a minimal level of expertise and fluency within a knowledge domain ( Bransford et al. , 2000 ; Crawford and Brophy, 2006 ). What distinguishes experts from novices, in addition to their deeper knowledge of the subject, is their recognition of patterns in information, their ability to see relationships among disparate facts and concepts, and their capacity for organizing content into conceptual frameworks or schemata ( Bransford et al. , 2000 ; Sawyer, 2005 ).

Such expertise is often lacking in the traditional classroom. For students attempting to grapple with new subject matter, many kinds of problems that are presented in high school or college courses or that arise in the real world can be solved merely by applying newly learned algorithms or procedural knowledge. With practice, problem solving of this kind can become routine and is often considered to represent mastery of a subject, producing what Sternberg refers to as “pseudoexperts” ( Sternberg, 2003 ). But beyond such routine use of content knowledge the instructor's goal must be to produce students who have gained the HOCS needed to apply, analyze, synthesize, and evaluate knowledge ( Crowe et al. , 2008 ). The aim is to produce students who know enough about a field to grasp meaningful patterns of information, who can readily retrieve relevant knowledge from memory, and who can apply such knowledge effectively to novel problems. This condition is referred to as adaptive expertise ( Hatano and Ouro, 2003 ; Schwartz et al. , 2005 ). Instead of applying already mastered procedures, adaptive experts are able to draw on their knowledge to invent or adapt strategies for solving unique or novel problems within a knowledge domain. They are also able, ideally, to transfer conceptual frameworks and schemata from one domain to another (e.g., Schwartz et al. , 2005 ). Such flexible, innovative application of knowledge is what results in inventive or creative solutions to problems ( Crawford and Brophy, 2006 ; Crawford, 2007 ).

Promoting Creative Problem Solving in the College Classroom

In most college courses, instructors teach science primarily through lectures and textbooks that are dominated by facts and algorithmic processing rather than by concepts, principles, and evidence-based ways of thinking. This is despite ample evidence that many students gain little new knowledge from traditional lectures ( Hrepic et al. , 2007 ). Moreover, it is well documented that these methods engender passive learning rather than active engagement, boredom instead of intellectual excitement, and linear thinking rather than cognitive flexibility (e.g., Halpern and Hakel, 2003 ; Nelson, 2008 ; Perkins and Wieman, 2008 ). Cognitive flexibility, as noted, is one of the three core mental executive functions involved in creative problem solving ( Ausubel, 1963 , 2000 ). The capacity to apply ideas creatively in new contexts, referred to as the ability to “transfer” knowledge (see Mestre, 2005 ), requires that learners have opportunities to actively develop their own representations of information to convert it to a usable form. Especially when a knowledge domain is complex and fraught with ill-structured information, as in a typical introductory college biology course, instruction that emphasizes active-learning strategies is demonstrably more effective than traditional linear teaching in reducing failure rates and in promoting learning and transfer (e.g., Freeman et al. , 2007 ). Furthermore, there is already some evidence that inclusion of creativity training as part of a college curriculum can have positive effects. Hunsaker (2005) has reviewed a number of such studies. He cites work by McGregor (2001) , for example, showing that various creativity training programs including brainstorming and creative problem solving increase student scores on tests of creative-thinking abilities.

Model creativity—students develop creativity when instructors model creative thinking and inventiveness.

Repeatedly encourage idea generation—students need to be reminded to generate their own ideas and solutions in an environment free of criticism.

Cross-fertilize ideas—where possible, avoid teaching in subject-area boxes: a math box, a social studies box, etc; students' creative ideas and insights often result from learning to integrate material across subject areas.

Build self-efficacy—all students have the capacity to create and to experience the joy of having new ideas, but they must be helped to believe in their own capacity to be creative.

Constantly question assumptions—make questioning a part of the daily classroom exchange; it is more important for students to learn what questions to ask and how to ask them than to learn the answers.

Imagine other viewpoints—students broaden their perspectives by learning to reflect upon ideas and concepts from different points of view.

How Is Creativity Related to Critical Thinking and the Higher-Order Cognitive Skills?

It is not uncommon to associate creativity and ingenuity with scientific reasoning ( Sawyer, 2005 ; 2006 ). When instructors apply scientific teaching strategies ( Handelsman et al. , 2004 ; DeHaan, 2005 ; Wood, 2009 ) by using instructional methods based on learning research, according to Ebert-May and Hodder ( 2008 ), “we see students actively engaged in the thinking, creativity, rigor, and experimentation we associate with the practice of science—in much the same way we see students learn in the field and in laboratories” (p. 2). Perkins and Wieman (2008) note that “To be successful innovators in science and engineering, students must develop a deep conceptual understanding of the underlying science ideas, an ability to apply these ideas and concepts broadly in different contexts, and a vision to see their relevance and usefulness in real-world applications … An innovator is able to perceive and realize potential connections and opportunities better than others” (pp. 181–182). The results of Scott et al. (2004) suggest that nontraditional courses in science that are based on constructivist principles and that use strategies of scientific teaching to promote the HOCS and enhance content mastery and dexterity in scientific thinking ( Handelsman et al. , 2007 ; Nelson, 2008 ) also should be effective in promoting creativity and cognitive flexibility if students are explicitly guided to learn these skills.

Creativity is an essential element of problem solving ( Mumford et al. , 1991 ; Runco, 2004 ) and of critical thinking ( Abrami et al. , 2008 ). As such, it is common to think of applications of creativity such as inventiveness and ingenuity among the HOCS as defined in Bloom's taxonomy ( Crowe et al. , 2008 ). Thus, it should come as no surprise that creativity, like other elements of the HOCS, can be taught most effectively through inquiry-based instruction, informed by constructivist theory ( Ausubel, 1963 , 2000 ; Duch et al. , 2001 ; Nelson, 2008 ). In a survey of 103 instructors who taught college courses that included creativity instruction, Bull et al. (1995) asked respondents to rate the importance of various course characteristics for enhancing student creativity. Items ranking high on the list were: providing a social climate in which students feels safe, an open classroom environment that promotes tolerance for ambiguity and independence, the use of humor, metaphorical thinking, and problem defining. Many of the responses emphasized the same strategies as those advanced to promote creative problem solving (e.g., Mumford et al. , 1991 ; McFadzean, 2002 ; Treffinger and Isaksen, 2005 ) and critical thinking ( Abrami et al. , 2008 ).

In a careful meta-analysis, Scott et al. (2004) examined 70 instructional interventions designed to enhance and measure creative performance. The results were striking. Courses that stressed techniques such as critical thinking, convergent thinking, and constraint identification produced the largest positive effect sizes. More open techniques that provided less guidance in strategic approaches had less impact on the instructional outcomes. A striking finding was the effectiveness of being explicit; approaches that clearly informed students about the nature of creativity and offered clear strategies for creative thinking were most effective. Approaches such as social modeling, cooperative learning, and case-based (project-based) techniques that required the application of newly acquired knowledge were found to be positively correlated to high effect sizes. The most clear-cut result to emerge from the Scott et al. (2004) study was simply to confirm that creativity instruction can be highly successful in enhancing divergent thinking, problem solving, and imaginative performance. Most importantly, of the various cognitive processes examined, those linked to the generation of new ideas such as problem finding, conceptual combination, and idea generation showed the greatest improvement. The success of creativity instruction, the authors concluded, can be attributed to “developing and providing guidance concerning the application of requisite cognitive capacities … [and] a set of heuristics or strategies for working with already available knowledge” (p. 382).

Many of the scientific teaching practices that have been shown by research to foster content mastery and HOCS, and that are coming more widely into use, also would be consistent with promoting creativity. Wood (2009) has recently reviewed examples of such practices and how to apply them. These include relatively small modifications of the traditional lecture to engender more active learning, such as the use of concept tests and peer instruction ( Mazur, 1996 ), Just-in-Time-Teaching techniques ( Novak et al. , 1999 ), and student response systems known as “clickers” ( Knight and Wood, 2005 ; Crossgrove and Curran, 2008 ), all designed to allow the instructor to frequently and effortlessly elicit and respond to student thinking. Other strategies can transform the lecture hall into a workshop or studio classroom ( Gaffney et al. , 2008 ) where the teaching curriculum may emphasize problem-based (also known as project-based or case-based) learning strategies ( Duch et al. , 2001 ; Ebert-May and Hodder, 2008 ) or “community-based inquiry” in which students engage in research that enhances their critical-thinking skills ( Quitadamo et al. , 2008 ).

Another important approach that could readily subserve explicit creativity instruction is the use of computer-based interactive simulations, or “sims” ( Perkins and Wieman, 2008 ) to facilitate inquiry learning and effective, easy self-assessment. An example in the biological sciences would be Neurons in Action ( http://neuronsinaction.com/home/main ). In such educational environments, students gain conceptual understanding of scientific ideas through interactive engagement with materials (real or virtual), with each other, and with instructors. Following the tenets of scientific teaching, students are encouraged to pose and answer their own questions, to make sense of the materials, and to construct their own understanding. The question I pose here is whether an additional focus—guiding students to meet these challenges in a context that explicitly promotes creativity—would enhance learning and advance students' progress toward adaptive expertise?

Assessment of Creativity

To teach creativity, there must be measurable indicators to judge how much students have gained from instruction. Educational programs intended to teach creativity became popular after the Torrance Tests of Creative Thinking (TTCT) was introduced in the 1960s ( Torrance, 1974 ). But it soon became apparent that there were major problems in devising tests for creativity, both because of the difficulty of defining the construct and because of the number and complexity of elements that underlie it. Tests of intelligence and other personality characteristics on creative individuals revealed a host of related traits such as verbal fluency, metaphorical thinking, flexible decision making, tolerance of ambiguity, willingness to take risks, autonomy, divergent thinking, self-confidence, problem finding, ideational fluency, and belief in oneself as being “creative” ( Barron and Harrington, 1981 ; Tardif and Sternberg, 1988 ; Runco and Nemiro, 1994 ; Snyder et al. , 2004 ). Many of these traits have been the focus of extensive research of recent decades, but, as noted above, creativity is not defined by any one trait; there is now reason to believe that it is the interplay among the cognitive and affective processes that underlie inventiveness and the ability to find novel solutions to a problem.

Although the early creativity researchers recognized that assessing divergent thinking as a measure of creativity required tests for other underlying capacities ( Guilford, 1950 ; Torrance, 1974 ), these workers and their colleagues nonetheless believed that a high score for divergent thinking alone would correlate with real creative output. Unfortunately, no such correlation was shown ( Barron and Harrington, 1981 ). Results produced by many of the instruments initially designed to measure various aspects of creative thinking proved to be highly dependent on the test itself. A review of several hundred early studies showed that an individual's creativity score could be affected by simple test variables, for example, how the verbal pretest instructions were worded ( Barron and Harrington, 1981 , pp. 442–443). Most scholars now agree that divergent thinking, as originally defined, was not an adequate measure of creativity. The process of creative thinking requires a complex combination of elements that include cognitive flexibility, memory control, inhibitory control, and analogical thinking, enabling the mind to free-range and analogize, as well as to focus and test.

More recently, numerous psychometric measures have been developed and empirically tested (see Plucker and Renzulli, 1999 ) that allow more reliable and valid assessment of specific aspects of creativity. For example, the creativity quotient devised by Snyder et al. (2004) tests the ability of individuals to link different ideas and different categories of ideas into a novel synthesis. The Wallach–Kogan creativity test ( Wallach and Kogan, 1965 ) explores the uniqueness of ideas associated with a stimulus. For a more complete list and discussion, see the Creativity Tests website ( www.indiana.edu/∼bobweb/Handout/cretv_6.html ).

The most widely used measure of creativity is the TTCT, which has been modified four times since its original version in 1966 to take into account subsequent research. The TTCT-Verbal and the TTCT-Figural are two versions ( Torrance, 1998 ; see http://ststesting.com/2005giftttct.html ). The TTCT-Verbal consists of five tasks; the “stimulus” for each task is a picture to which the test-taker responds briefly in writing. A sample task that can be viewed from the TTCT Demonstrator website asks, “Suppose that people could transport themselves from place to place with just a wink of the eye or a twitch of the nose. What might be some things that would happen as a result? You have 3 min.” ( www.indiana.edu/∼bobweb/Handout/d3.ttct.htm ).

In the TTCT-Figural, participants are asked to construct a picture from a stimulus in the form of a partial line drawing given on the test sheet (see example below; Figure 1 ). Specific instructions are to “Add lines to the incomplete figures below to make pictures out of them. Try to tell complete stories with your pictures. Give your pictures titles. You have 3 min.” In the introductory materials, test-takers are urged to “… think of a picture or object that no one else will think of. Try to make it tell as complete and as interesting a story as you can …” ( Torrance et al. , 2008 , p. 2).

Figure 1. Sample figural test item from the TTCT Demonstrator website ( www.indiana.edu/∼bobweb/Handout/d3.ttct.htm ).

How would an instructor in a biology course judge the creativity of students' responses to such an item? To assist in this task, the TTCT has scoring and norming guides ( Torrance, 1998 ; Torrance et al. , 2008 ) with numerous samples and responses representing different levels of creativity. The guides show sample evaluations based upon specific indicators such as fluency, originality, elaboration (or complexity), unusual visualization, extending or breaking boundaries, humor, and imagery. These examples are easy to use and provide a high degree of validity and generalizability to the tests. The TTCT has been more intensively researched and analyzed than any other creativity instrument, and the norming samples have longitudinal validations and high predictive validity over a wide age range. In addition to global creativity scores, the TTCT is designed to provide outcome measures in various domains and thematic areas to allow for more insightful analysis ( Kaufman and Baer, 2006 ). Kim (2006) has examined the characteristics of the TTCT, including norms, reliability, and validity, and concludes that the test is an accurate measure of creativity. When properly used, it has been shown to be fair in terms of gender, race, community status, and language background. According to Kim (2006) and other authorities in the field ( McIntyre et al. , 2003 ; Scott et al. , 2004 ), Torrance's research and the development of the TTCT have provided groundwork for the idea that creative levels can be measured and then increased through instruction and practice.

SCIENTIFIC TEACHING TO PROMOTE CREATIVITY

How could creativity instruction be integrated into scientific teaching.

Guidelines for designing specific course units that emphasize HOCS by using strategies of scientific teaching are now available from the current literature. As an example, Karen Cloud-Hansen and colleagues ( Cloud-Hansen et al. , 2008 ) describe a course titled, “Ciprofloxacin Resistance in Neisseria gonorrhoeae .” They developed this undergraduate seminar to introduce college freshmen to important concepts in biology within a real-world context and to increase their content knowledge and critical-thinking skills. The centerpiece of the unit is a case study in which teams of students are challenged to take the role of a director of a local public health clinic. One of the county commissioners overseeing the clinic is an epidemiologist who wants to know “how you plan to address the emergence of ciprofloxacin resistance in Neisseria gonorrhoeae ” (p. 304). State budget cuts limit availability of expensive antibiotics and some laboratory tests to patients. Student teams are challenged to 1) develop a plan to address the medical, economic, and political questions such a clinic director would face in dealing with ciprofloxacin-resistant N. gonorrhoeae ; 2) provide scientific data to support their conclusions; and 3) describe their clinic plan in a one- to two-page referenced written report.

Throughout the 3-wk unit, in accordance with the principles of problem-based instruction ( Duch et al. , 2001 ), course instructors encourage students to seek, interpret, and synthesize their own information to the extent possible. Students have access to a variety of instructional formats, and active-learning experiences are incorporated throughout the unit. These activities are interspersed among minilectures and give the students opportunities to apply new information to their existing base of knowledge. The active-learning activities emphasize the key concepts of the minilectures and directly confront common misconceptions about antibiotic resistance, gene expression, and evolution. Weekly classes include question/answer/discussion sessions to address student misconceptions and 20-min minilectures on such topics as antibiotic resistance, evolution, and the central dogma of molecular biology. Students gather information about antibiotic resistance in N. gonorrhoeae , epidemiology of gonorrhea, and treatment options for the disease, and each team is expected to formulate a plan to address ciprofloxacin resistance in N. gonorrhoeae .

In this project, the authors assessed student gains in terms of content knowledge regarding topics covered such as the role of evolution in antibiotic resistance, mechanisms of gene expression, and the role of oncogenes in human disease. They also measured HOCS as gains in problem solving, according to a rubric that assessed self-reported abilities to communicate ideas logically, solve difficult problems about microbiology, propose hypotheses, analyze data, and draw conclusions. Comparing the pre- and posttests, students reported significant learning of scientific content. Among the thinking skill categories, students demonstrated measurable gains in their ability to solve problems about microbiology but the unit seemed to have little impact on their more general perceived problem-solving skills ( Cloud-Hansen et al. , 2008 ).

What would such a class look like with the addition of explicit creativity-promoting approaches? Would the gains in problem-solving abilities have been greater if during the minilectures and other activities, students had been introduced explicitly to elements of creative thinking from the Sternberg and Williams (1998) list described above? Would the students have reported greater gains if their instructors had encouraged idea generation with weekly brainstorming sessions; if they had reminded students to cross-fertilize ideas by integrating material across subject areas; built self-efficacy by helping students believe in their own capacity to be creative; helped students question their own assumptions; and encouraged students to imagine other viewpoints and possibilities? Of most relevance, could the authors have been more explicit in assessing the originality of the student plans? In an experiment that required college students to develop plans of a different, but comparable, type, Osborn and Mumford (2006) created an originality rubric ( Figure 2 ) that could apply equally to assist instructors in judging student plans in any course. With such modifications, would student gains in problem-solving abilities or other HOCS have been greater? Would their plans have been measurably more imaginative?

Figure 2. Originality rubric (adapted from Osburn and Mumford, 2006 , p. 183).

Answers to these questions can only be obtained when a course like that described by Cloud-Hansen et al. (2008) is taught with explicit instruction in creativity of the type I described above. But, such answers could be based upon more than subjective impressions of the course instructors. For example, students could be pretested with items from the TTCT-Verbal or TTCT-Figural like those shown. If, during minilectures and at every contact with instructors, students were repeatedly reminded and shown how to be as creative as possible, to integrate material across subject areas, to question their own assumptions and imagine other viewpoints and possibilities, would their scores on TTCT posttest items improve? Would the plans they formulated to address ciprofloxacin resistance become more imaginative?

Recall that in their meta-analysis, Scott et al. (2004) found that explicitly informing students about the nature of creativity and offering strategies for creative thinking were the most effective components of instruction. From their careful examination of 70 experimental studies, they concluded that approaches such as social modeling, cooperative learning, and case-based (project-based) techniques that required the application of newly acquired knowledge were positively correlated with high effect sizes. The study was clear in confirming that explicit creativity instruction can be successful in enhancing divergent thinking and problem solving. Would the same strategies work for courses in ecology and environmental biology, as detailed by Ebert-May and Hodder (2008) , or for a unit elaborated by Knight and Wood (2005) that applies classroom response clickers?

Finally, I return to my opening question with the fictional Dr. Dunne. Could a weekly brainstorming “invention session” included in a course like those described here serve as the site where students are introduced to concepts and strategies of creative problem solving? As frequently applied in schools of engineering ( Paulus and Nijstad, 2003 ), brainstorming provides an opportunity for the instructor to pose a problem and to ask the students to suggest as many solutions as possible in a brief period, thus enhancing ideational fluency. Here, students can be encouraged explicitly to build on the ideas of others and to think flexibly. Would brainstorming enhance students' divergent thinking or creative abilities as measured by TTCT items or an originality rubric? Many studies have demonstrated that group interactions such as brainstorming, under the right conditions, can indeed enhance creativity ( Paulus and Nijstad, 2003 ; Scott et al. , 2004 ), but there is little information from an undergraduate science classroom setting. Intellectual Ventures, a firm founded by Nathan Myhrvold, the creator of Microsoft's Research Division, has gathered groups of engineers and scientists around a table for day-long sessions to brainstorm about a prearranged topic. Here, the method seems to work. Since it was founded in 2000, Intellectual Ventures has filed hundreds of patent applications in more than 30 technology areas, applying the “invention session” strategy ( Gladwell, 2008 ). Currently, the company ranks among the top 50 worldwide in number of patent applications filed annually. Whether such a technique could be applied successfully in a college science course will only be revealed by future research.

Abrami P. C., Bernard R. M., Borokhovski E., Wadem A., Surkes M. A., Tamim R., Zhang D. ( 2008 ). Instructional interventions affecting critical thinking skills and dispositions: a stage 1 meta-analysis . Rev. Educ. Res 78 , 1102-1134. Google Scholar
Amabile T. M. ( 1996 ). Creativity in Context , Boulder, CO: Westview Press. Google Scholar
Amabile T. M., Barsade S. G., Mueller J. S., Staw B. M. ( 2005 ). Affect and creativity at work . Admin. Sci. Q 50 , 367-403. Google Scholar
Ausubel D. ( 1963 ). The Psychology of Meaningful Verbal Learning , New York: Grune and Stratton. Google Scholar
Ausubel B. ( 2000 ). The Acquisition and Retention of Knowledge: A Cognitive View , Boston, MA: Kluwer Academic Publishers. Google Scholar
Banaji S., Burn A., Buckingham D. ( 2006 ). The Rhetorics of Creativity: A Review of the Literature , accessed 29 December 2008 London: Centre for the Study of Children, Youth and Media, www.creativepartnerships.com/data/files/rhetorics-of-creativity-12.pdf . Google Scholar
Barron F., Harrington D. M. ( 1981 ). Creativity, intelligence and personality . Ann. Rev. Psychol 32 , 439-476. Google Scholar
Beller M. ( 1999 ). Quantum Dialogue: The Making of a Revolution , Chicago, IL: University of Chicago Press. Google Scholar
Blair C., Razza R. P. ( 2007 ). Relating effortful control, executive function, and false belief understanding to emerging math and literacy ability in kindergarten . Child Dev 78 , 647-663. Medline , Google Scholar
Bodrova E., Leong D. J. ( 2001 ). The Tool of the Mind: a case study of implementing the Vygotskian approach In: American Early Childhood and Primary Classrooms , Geneva, Switzerland: UNESCO International Bureau of Education. Google Scholar
Bransford J. D.Brown A. L.Cocking R. R. ( 2000 ). How People Learn: Brain, Mind, Experience, and School , Washington, DC: National Academies Press. Google Scholar
Brophy D. R. ( 2006 ). A comparison of individual and group efforts to creatively solve contrasting types of problems . Creativity Res. J 18 , 293-315. Google Scholar
Bruner J. ( 1965 ). The growth of mind . Am. Psychol 20 , 1007-1017. Medline , Google Scholar
Bull K. S., Montgomery D., Baloche L. ( 1995 ). Teaching creativity at the college level: a synthesis of curricular components perceived as important by instructors . Creativity Res. J 8 , 83-90. Google Scholar
Burton R. ( 2008 ). On Being Certain: Believing You Are Right Even When You're Not , New York: St. Martin's Press. Google Scholar
Cloud-Hanson K. A., Kuehner J. N., Tong L., Miller S., Handelsman J. ( 2008 ). Money, sex and drugs: a case study to teach the genetics of antibiotic resistance . CBE Life Sci. Educ 7 , 302-309. Medline , Google Scholar
Craft A. ( 2000 ). Teaching Creativity: Philosophy and Practice , New York: Routledge. Google Scholar
Crawford V. M. ( 2007 ). Adaptive expertise as knowledge building in science teachers' problem solving accessed 1 July 2008 Proceedings of the Second European Cognitive Science Conference Delphi, Greece http://ctl.sri.com/publications/downloads/Crawford_EuroCogSci07Proceedings.pdf . Google Scholar
Crawford V. M., Brophy S. ( 2006 ). Adaptive Expertise: Theory, Methods, Findings, and Emerging Issues; September 2006 In: accessed 1 July 2008 Menlo Park, CA: SRI International, http://ctl.sri.com/publications/downloads/AESymposiumReportOct06.pdf . Google Scholar
Crossgrove K., Curran K. L. ( 2008 ). Using clickers in nonmajors- and majors-level biology courses: student opinion, learning, and long-term retention of course material . CBE Life Sci. Educ 7 , 146-154. Link , Google Scholar
Crowe A., Dirks C., Wenderoth M. P. ( 2008 ). Biology in bloom: implementing Bloom's taxonomy to enhance student learning in biology . CBE Life Sci. Educ 7 , 368-381. Link , Google Scholar
Davidson M. C., Amso D., Anderson L. C., Diamond A. ( 2006 ). Development of cognitive control and executive functions from 4–13 years: evidence from manipulations of memory, inhibition, and task switching . Neuropsychologia 44 , 2037-2078. Medline , Google Scholar
DeHaan R. L. ( 2005 ). The impending revolution in undergraduate science education . J. Sci. Educ. Technol 14 , 253-270. Google Scholar
Diamond A., Barnett W. S., Thomas J., Munro S. ( 2007 ). Preschool program improves cognitive control . Science 318 , 1387-1388. Medline , Google Scholar
Duch B. J., Groh S. E., Allen D. E. ( 2001 ). The Power of Problem-based Learning , Sterling, VA: Stylus Publishers. Google Scholar
Durston S., Davidson M. C., Thomas K. M., Worden M. S., Tottenham N., Martinez A., Watts R., Ulug A. M., Caseya B. J. ( 2003 ). Parametric manipulation of conflict and response competition using rapid mixed-trial event-related fMRI . Neuroimage 20 , 2135-2141. Medline , Google Scholar
Ebert-May D., Hodder J. ( 2008 ). Pathways to Scientific Teaching , Sunderland, MA: Sinauer. Google Scholar
Finke R. A., Ward T. B., Smith S. M. ( 1996 ). Creative Cognition: Theory, Research and Applications , Boston, MA: MIT Press. Google Scholar
Freeman S., O'Connor E., Parks J. W., Cunningham M., Hurley D., Haak D., Dirks C., Wenderoth M. P. ( 2007 ). Prescribed active learning increases performance in introductory biology . CBE Life Sci. Educ 6 , 132-139. Link , Google Scholar
Gabora L. ( 2002 ). Hewett T.Kavanagh E. Cognitive mechanisms underlying the creative process Proceedings of the Fourth International Conference on Creativity and Cognition 2002 October 13–16 Loughborough University, United Kingdom 126-133. Google Scholar
Gaffney J.D.H., Richards E., Kustusch M. B., Ding L., Beichner R. ( 2008 ). Scaling up education reform . J. Coll. Sci. Teach 37 , 48-53. Google Scholar
Gardner H. ( 1993 ). Creating Minds: An Anatomy of Creativity Seen through the Lives of Freud, Einstein, Picasso, Stravinsky, Eliot, Graham, and Ghandi In: New York: Harper Collins. Google Scholar
Gladwell M. ( 2008 ). In the air; who says big ideas are rare? The New Yorker accessed 19 May 2008 www.newyorker.com/reporting/2008/05/12/080512fa_fact_gladwell . Google Scholar
Guilford J. P. ( 1950 ). Creativity . Am. Psychol 5 , 444-454. Medline , Google Scholar
Hake R. ( 2005 ). The physics education reform effort: a possible model for higher education . Natl. Teach. Learn. Forum 15 , 1-6. Google Scholar
Halpern D. E., Hakel M. D. ( 2003 ). Applying the science of learning to the university and beyond . Change 35 , 36-42. Google Scholar
Handelsman J. ( 2004 ). Scientific teaching . Science 304 , 521-522. Medline , Google Scholar
Handelsman J, Miller S., Pfund C. ( 2007 ). Scientific Teaching , New York: W. H. Freeman and Co. Google Scholar
Haring-Smith T. ( 2006 ). Creativity research review: some lessons for higher education. Association of American Colleges and Universities . Peer Rev 8 , 23-27. Google Scholar
Hatano G., Ouro Y. ( 2003 ). Commentary: reconceptualizing school learning using insight from expertise research . Educ. Res 32 , 26-29. Google Scholar
Hrepic Z., Zollman D. A., Rebello N. S. ( 2007 ). Comparing students' and experts' understanding of the content of a lecture . J. Sci. Educ. Technol 16 , 213-224. Google Scholar
Hunsaker S. L. ( 2005 ). Outcomes of creativity training programs . Gifted Child Q 49 , 292-298. Google Scholar
Kaufman J. C., Baer J. ( 2006 ). Intelligent testing with Torrance . Creativity Res. J 18 , 99-102. Google Scholar
Kaufman J. C., Beghetto R. A. ( 2008 , Ed. R. L. DeHaanK.M.V. Narayan , Exploring mini-C: creativity across cultures In: Education for Innovation: Implications for India, China and America , Rotterdam, The Netherlands: Sense Publishers, 165-180. Google Scholar
Kaufman J. C., Sternberg R. J. ( 2007 ). Creativity . Change 39 , 55-58. Google Scholar
Kim K. H. ( 2006 ). Can we trust creativity tests: a review of the Torrance Tests of Creative Thinking (TTCT) . Creativity Res. J 18 , 3-14. Google Scholar
Knight J. K., Wood W. B. ( 2005 ). Teaching more by lecturing less . Cell Biol. Educ 4 , 298-310. Link , Google Scholar
Cetina Knorr K. ( 1995 , Ed. S. JasanoffG. MarkleJ. PetersenT. Pinch , Laboratory studies: the cultural approach to the study of science In: Handbook of Science and Technology Studies , Thousand Oaks, CA: Sage Publications, 140-166. Google Scholar
Koestler A. ( 1964 ). The Act of Creation , New York: Macmillan. Google Scholar
Latour B., Woolgar S. ( 1986 ). Laboratory Life: The Construction of Scientific Facts , Princeton, NJ: Princeton University Press. Google Scholar
MacKinnon D. W. ( 1978 , Ed. D. W. MacKinnon , What makes a person creative? In: In Search of Human Effectiveness , New York: Universe Books, 178-186. Google Scholar
Martindale C. ( 1999 , Ed. R. J. Sternberg , Biological basis of creativity In: Handbook of Creativity , Cambridge, United Kingdom: Cambridge University Press, 137-152. Google Scholar
Mazur E. ( 1996 ). Peer Instruction: A User's Manual , Upper Saddle River, NJ: Prentice Hall. Google Scholar
McFadzean E. ( 2002 ). Developing and supporting creative problem-solving teams: Part 1—a conceptual model . Manage. Decis 40 , 463-475. Google Scholar
McGregor G. D. ( 2001 ). Creative thinking instruction for a college study skills program: a case study. . Dissert Abstr. Intl 62 , 3293A UMI No. AAT 3027933. Google Scholar
McIntyre F. S., Hite R. E., Rickard M. K. ( 2003 ). Individual characteristics and creativity in the marketing classroom: exploratory insights . J. Mark. Educ 25 , 143-149. Google Scholar
Mestre J. P. ( 2005 ). Transfer of Learning: From a Modern Multidisciplinary Perspective , Greenwich, CT: Information Age Publishing. Google Scholar
Mumford M. D., Mobley M. I., Uhlman C. E., Reiter-Palmon R., Doares L. M. ( 1991 ). Process analytic models of creative capacities . Creativity Res. J 4 , 91-122. Google Scholar
National Research Council ( 2007 ). Rising Above the Gathering Storm: Energizing and Employing America for a Brighter Economic Future, Committee on Science, Engineering and Public Policy In: Washington, DC: National Academies Press. Google Scholar
Neisser U. ( 1963 ). The multiplicity of thought . Br. J. Psychol 54 , 1-14. Medline , Google Scholar
Nelson C. E. ( 2008 ). Teaching evolution (and all of biology) more effectively: strategies for engagement, critical reasoning, and confronting misconceptions Integrative and Comparative Biology Advance Access accessed 15 September 2008 http://icb.oxfordjournals.org/cgi/reprint/icn027v1.pdf . Google Scholar
Novak G, Gavrin A., Christian W, Patterson E. ( 1999 ). Just-in-Time Teaching: Blending Active Learning with Web Technology , San Francisco, CA: Pearson Benjamin Cummings. Google Scholar
Osborn A. F. ( 1948 ). Your Creative Power , New York: Scribner. Google Scholar
Osborn A. F. ( 1979 ). Applied Imagination , New York: Scribner. Google Scholar
Osburn H. K., Mumford M. D. ( 2006 ). Creativity and planning: training interventions to develop creative problem-solving skills . Creativity Res. J 18 , 173-190. Google Scholar
Paulus P. B., Nijstad B. A. ( 2003 ). Group Creativity: Innovation through Collaboration , New York: Oxford University Press. Google Scholar
Perkins K. K., Wieman C. E. ( 2008 , Ed. R. L. DeHaanK.M.V. Narayan , Innovative teaching to promote innovative thinking In: Education for Innovation: Implications for India, China and America , Rotterdam, The Netherlands: Sense Publishers, 181-210. Google Scholar
Plucker J. A., Renzulli J. S. ( 1999 , Ed. R. J. Sternberg , Psychometric approaches to the study of human creativity In: Handbook of Creativity , Cambridge, United Kingdom: Cambridge University Press, 35-61. Google Scholar
Quitadamo I. J., Faiola C. L., Johnson J. E., Kurtz M. J. ( 2008 ). Community-based inquiry improves critical thinking in general education biology . CBE Life Sci. Educ 7 , 327-337. Link , Google Scholar
Runco M. A. ( 2004 ). Creativity . Annu. Rev. Psychol 55 , 657-687. Medline , Google Scholar
Runco M. A., Nemiro J. ( 1994 ). Problem finding, creativity, and giftedness . Roeper Rev 16 , 235-241. Google Scholar
Sawyer R. K. ( 2005 ). Educating for Innovation Thinking Skills Creativity accessed 13 August 2008 1 41-48 www.artsci.wustl.edu/∼ksawyer/PDFs/Thinkjournal.pdf . Google Scholar
Sawyer R. K. ( 2006 ). Explaining Creativity: The Science of Human Innovation , New York: Oxford University Press. Google Scholar
Schwartz D. L., Bransford J. D., Sears D. ( 2005 , Ed. J. P. Mestre , Efficiency and innovation in transfer In: Transfer of Learning from a Modern Multidisciplinary Perspective , Greenwich, CT: Information Age Publishing, 1-51. Google Scholar
Scott G., Leritz L. E., Mumford M. D. ( 2004 ). The effectiveness of creativity training: a quantitative review . Creativity Res. J 16 , 361-388. Google Scholar
Simonton D. K. ( 1975 ). Sociocultural context of individual creativity: a transhistorical time-series analysis . J. Pers. Soc. Psychol 32 , 1119-1133. Medline , Google Scholar
Simonton D. K. ( 2004 ). Creativity in Science: Chance, Logic, Genius, and Zeitgeist , Oxford, United Kingdom: Cambridge University Press. Google Scholar
Sloman S. ( 1996 ). The empirical case for two systems of reasoning . Psychol. Bull 9 , 3-22. Google Scholar
Smith G. F. ( 1998 ). Idea generation techniques: a formulary of active ingredients . J. Creative Behav 32 , 107-134. Google Scholar
Snyder A., Mitchell J., Bossomaier T., Pallier G. ( 2004 ). The creativity quotient: an objective scoring of ideational fluency . Creativity Res. J 16 , 415-420. Google Scholar
Sternberg R. J. ( 2003 ). What is an “expert student?” . Educ. Res. 32 , 5-9. Google Scholar
Sternberg R., Williams W. M. ( 1998 ). Teaching for creativity: two dozen tips accessed 25 March 2008 www.cdl.org/resource-library/articles/teaching_creativity.php . Google Scholar
Tardif T. Z., Sternberg R. J. ( 1988 , Ed. R. J. Sternberg , What do we know about creativity? In: The Nature of Creativity , New York: Cambridge University Press, 429-440. Google Scholar
Torrance E. P. ( 1974 ). Norms and Technical Manual for the Torrance Tests of Creative Thinking , Bensenville, IL: Scholastic Testing Service. Google Scholar
Torrance E. P. ( 1998 ). The Torrance Tests of Creative Thinking Norms—Technical Manual Figural (Streamlined) Forms A and B , Bensenville, IL: Scholastic Testing Service. Google Scholar
Torrance E. P., Ball O. E., Safter H. T. ( 2008 ). Torrance Tests of Creative Thinking: Streamlined Scoring Guide for Figural Forms A and B , Bensenville, IL: Scholastic Testing Service. Google Scholar
Treffinger D. J., Isaksen S. G. ( 2005 ). Creative problem solving: the history, development, and implications for gifted education and talent development . Gifted Child Q 49 , 342-357. Google Scholar
Vandervert L. R., Schimpf P. H., Liu H. ( 2007 ). How working memory and the cerebellum collaborate to produce creativity and innovation . Creativity Res. J 9 , 1-18. Google Scholar
Wallach M. A., Kogan N. ( 1965 ). Modes of Thinking in Young Children: A Study of the Creativity-Intelligence Distinction , New York: Holt, Rinehart and Winston. Google Scholar
Wood W. B. ( 2009 ). Innovations in undergraduate biology teaching and why we need them . Annu. Rev. Cell Dev. Biol in press. Medline , Google Scholar
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TOWARDS ENHANCING CREATIVITY AND INNOVATION IN EDUCATION SYSTEM FOR YOUTH IN HAIL REGION 1 August 2023 | Advanced Education, Vol. 10, No. 22
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Promoting Creativity in Undergraduate Recreation and Leisure Services Classrooms: An Overview 19 March 2021 | SCHOLE: A Journal of Leisure Studies and Recreation Education, Vol. 38, No. 1
A Positive Association between Working Memory Capacity and Human Creativity: A Meta-Analytic Evidence 13 January 2023 | Journal of Intelligence, Vol. 11, No. 1
Students Creativity Through Digital Mind Map 26 July 2023
Pedagogical and School Practices to Foster Key Competences and Domain-General Literacy 23 August 2023
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Teaching design thinking as a tool to address complex public health challenges in public health students: a case study 12 April 2022 | BMC Medical Education, Vol. 22, No. 1
‘Allowing them to dream’: fostering creativity in mathematics undergraduates 26 May 2022 | Journal of Further and Higher Education, Vol. 46, No. 10
Interaction with metaphors enhances creative potential 1 July 2022 | Journal of Poetry Therapy, Vol. 35, No. 4
Creative problem solving in knowledge-rich contexts Trends in Cognitive Sciences, Vol. 26, No. 10
Teaching Protein–Ligand Interactions Using a Case Study on Tau in Alzheimer’s Disease 1 July 2022 | Journal of Chemical Education, Vol. 99, No. 8
Student approaches to creative processes when participating in an open-ended project in science 30 June 2022 | International Journal of Science Education, Vol. 44, No. 10
Arts, Machines, and Creative Education
Perceived Learning Effectiveness and Student Satisfaction
A Contribution to Scientific Creativity: A Validation Study Measuring Divergent Problem Solving Ability 3 September 2021 | Creativity Research Journal, Vol. 34, No. 2
Problem Solving and Digital Transformation: Acquiring Skills through Pretend Play in Kindergarten 28 January 2022 | Education Sciences, Vol. 12, No. 2
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Create Teaching Creativity through Training Management, Effectiveness Training, and Teacher Quality in the Covid-19 Pandemic 6 August 2021 | Journal of Ethnic and Cultural Studies, Vol. 8, No. 4
Creativity and technology in teaching and learning: a literature review of the uneasy space of implementation 11 January 2021 | Educational Technology Research and Development, Vol. 69, No. 4
Üstün Yetenekli Öğrencilerin Bilimsel Yaratıcılık ve Bilimsel Problem Çözme ile İlgili Öz Değerlendirmeleri 15 July 2021 | Yuzunci Yil Universitesi Egitim Fakultesi Dergisi
Cultivating creative thinking in engineering student teams: Can a computer‐mediated virtual laboratory help? 23 November 2020 | Journal of Computer Assisted Learning, Vol. 37, No. 2
Entrepreneurial competencies of undergraduate students: The case of universities in Nigeria The International Journal of Management Education, Vol. 19, No. 1
Promoting Creativity in General Education Mathematics Courses 5 August 2019 | PRIMUS, Vol. 31, No. 1
Methodological Considerations for Understanding Students’ Problem Solving Processes and Affective Trajectories During Game-Based Learning: A Data Fusion Approach 3 July 2021
The main trends in the process of building the creative potential of engineering students 18 June 2021 | E3S Web of Conferences, Vol. 274
Research on the Present Situation and Countermeasures of Cultivating Graduate Students’ Innovation Ability under Cooperative Innovation Environment Creative Education Studies, Vol. 09, No. 02
Innovation Centers and the Information Schools: The Influence of LIS Faculty Journal of Education for Library and Information Science, Vol. 61, No. 4
Biomimetics: teaching the tools of the trade 28 September 2020 | FEBS Open Bio, Vol. 10, No. 11
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Culturally Responsive Assessment of Physical Science Skills and Abilities: Development, Field Testing, Implementation, and Results 2 June 2020 | Journal of Advanced Academics, Vol. 31, No. 3
Culturally Responsive Assessment of Life Science Skills and Abilities: Development, Field Testing, Implementation, and Results 3 June 2020 | Journal of Advanced Academics, Vol. 31, No. 3
Curriculum Differentiation’s Capacity to Extend Gifted Students in Secondary Mixed-ability Science Classes 27 June 2020 | Talent, Vol. 10, No. 1
Student Motivation from and Resistance to Active Learning Rooted in Essential Science Practices 23 December 2017 | Research in Science Education, Vol. 50, No. 1
Integrating Entrepreneurship and Art to Improve Creative Problem Solving in Fisheries Education 27 February 2020 | Fisheries, Vol. 45, No. 2
Concepts Re-imagined: Relational Signs Beyond Definitional Rigidity 15 August 2020
Promoting Student Creativity and Inventiveness in Science and Engineering 24 October 2020
Teaching for Leadership, Innovation, and Creativity
Problem Çözme Becerileri Eğitim Programının Çocukların Karar Verme Becerileri Üzerindeki Etkisi 30 December 2019 | Erzincan Üniversitesi Eğitim Fakültesi Dergisi, Vol. 21, No. 3
Mento’s change model in teaching competency-based medical education 27 December 2019 | BMC Medical Education, Vol. 19, No. 1
The Effects of Individual Preparations on Group Creativity 21 January 2020
The Value of Creativity for Enhancing Translational Ecologies, Insights, and Discoveries 9 July 2019 | Frontiers in Psychology, Vol. 10
Using the International Classification of Functioning, Disability, and Health to Guide Students' Clinical Approach to Aging With Pathology Topics in Geriatric Rehabilitation, Vol. 35, No. 3
Impact of Brainstorming Strategy in Dealing With Knowledge Retention Skill: An Insight Into Special Learners' Needs In Saudi Arabia 1 January 2021 | MIER Journal of Educational Studies Trends & Practices
The potential of students’ creative disposition as a perspective to develop creative teaching and learning for senior high school biological science 12 March 2019 | Journal of Physics: Conference Series, Vol. 1157
Evaluating Remote Experiment from a Divergent Thinking Point of View 25 July 2018
Exploring Creative Education Practices and Implications: A Case study of National Chengchi University, Taiwan 4 April 2022 | Journal of Business and Economic Analysis, Vol. 02, No. 02
Exploring Creative Education Practices and Implications: A Case study of National Chengchi University, Taiwan 1 January 2020 | Journal of Business and Economic Analysis, Vol. 02, No. 02
Diverging from the Dogma: A Call to Train Creative Thinkers in Science 14 September 2018 | The Bulletin of the Ecological Society of America, Vol. 100, No. 1
Comparison of German and Japanese student teachers’ views on creativity in chemistry class 16 May 2018 | Asia-Pacific Science Education, Vol. 4, No. 1
The use of humour during a collaborative inquiry 27 August 2018 | International Journal of Science Education, Vol. 40, No. 14
Connecting creative coursework exposure and college student engagement across academic disciplines 29 August 2019 | Gifted and Talented International, Vol. 33, No. 1-2
Views of German chemistry teachers on creativity in chemistry classes and in general 1 January 2018 | Chemistry Education Research and Practice, Vol. 19, No. 3
Embedding Critical and Creative Thinking in Chemical Engineering Practice
Introducing storytelling to educational robotic activities
Investigating Undergraduates’ Perceptions of Science in Courses Taught Using the CREATE Strategy Journal of Microbiology & Biology Education, Vol. 19, No. 1
Teachers’ learning on the workshop of STS approach as a way of enhancing inventive thinking skills
Creativity Development Through Inquiry-Based Learning in Biomedical Sciences
The right tool for the right task: Structured techniques prove less effective on an ill-defined problem finding task Thinking Skills and Creativity, Vol. 26
The influential factors and hierarchical structure of college students’ creative capabilities—An empirical study in Taiwan Thinking Skills and Creativity, Vol. 26
Teacher perceptions of professional role and innovative teaching at elementary schools in Taiwan 10 November 2017 | Educational Research and Reviews, Vol. 12, No. 21
Evaluation of creative problem-solving abilities in undergraduate structural engineers through interdisciplinary problem-based learning 28 July 2016 | European Journal of Engineering Education, Vol. 42, No. 6
What Shall I Write Next? 19 September 2017
Inquiry-based Laboratory Activities on Drugs Analysis for High School Chemistry Learning 3 October 2017 | Journal of Physics: Conference Series, Vol. 895
BARRIERS TO STUDENTS’ CREATIVE EVALUATION OF UNEXPECTED EXPERIMENTAL FINDINGS 25 June 2017 | Journal of Baltic Science Education, Vol. 16, No. 3
Kyle J. Frantz ,
Melissa K. Demetrikopoulos ,
Shari L. Britner ,
Laura L. Carruth ,
Brian A. Williams ,
John L. Pecore ,
Robert L. DeHaan , and
Christopher T. Goode
Elizabeth Ambos, Monitoring Editor
A present absence: undergraduate course outlines and the development of student creativity across disciplines 3 October 2016 | Teaching in Higher Education, Vol. 22, No. 2
Exploring differences in creativity across academic majors for high-ability college students 16 February 2018 | Gifted and Talented International, Vol. 32, No. 1
Creativity in chemistry class and in general – German student teachers’ views 1 January 2017 | Chemistry Education Research and Practice, Vol. 18, No. 2
IMPORTANCE OF CREATIVITY IN ENTREPRENEURSHIP 1 January 2017
Accessing the Finest Minds
Science and Innovative Thinking for Technical and Organizational Development
Learning High School Biology in a Social Context Creative Education, Vol. 08, No. 15
Possibilities and limitations of integrating peer instruction into technical creativity education 6 September 2016 | Instructional Science, Vol. 44, No. 6
Creative Cognitive Processes in Higher Education 20 November 2014 | The Journal of Creative Behavior, Vol. 50, No. 4
An Evidence-Based Review of Creative Problem Solving Tools 6 April 2016 | Human Resource Development Review, Vol. 15, No. 2
Case-based exams for learning and assessment: Experiences in an information systems course
Case exams for assessing higher order learning: A comparative social media analytics usage exam
Beyond belief: Structured techniques prove more effective than a placebo intervention in a problem construction task Thinking Skills and Creativity, Vol. 19
A Belief System at the Core of Learning Science
Student Research Work and Modeled Situations in Order to Bridge the Gap between Basic Science Concepts and Those from Preventive and Clinical Practice. Meaningful Learning and Informed beneficience Creative Education, Vol. 07, No. 07
FOSTERING FIFTH GRADERS’ SCIENTIFIC CREATIVITY THROUGH PROBLEM-BASED LEARNING 25 October 2015 | Journal of Baltic Science Education, Vol. 14, No. 5
Scaffolding for Creative Product Possibilities in a Design-Based STEM Activity 16 November 2014 | Research in Science Education, Vol. 45, No. 5
Intuition and insight: two concepts that illuminate the tacit in science education 18 June 2015 | Studies in Science Education, Vol. 51, No. 2
Arts and crafts as adjuncts to STEM education to foster creativity in gifted and talented students 28 March 2015 | Asia Pacific Education Review, Vol. 16, No. 2
Initiatives Towards an Education for Creativity Procedia - Social and Behavioral Sciences, Vol. 180
Brian A. Couch ,
Tanya L. Brown ,
Tyler J. Schelpat ,
Mark J. Graham , and
Jennifer K. Knight
Michèle Shuster, Monitoring Editor
Kim Quillin , and
Stephen Thomas
Mary Lee Ledbetter, Monitoring Editor
The Design of IdeaWorks: Applying Social Learning Networks to Support Tertiary Education 21 July 2015
Video Games and Malevolent Creativity
Modelling a Laboratory for Ideas as a New Tool for Fostering Engineering Creativity Procedia Engineering, Vol. 100
“Development of Thinking Skills” Course: Teaching TRIZ in Academic Setting Procedia Engineering, Vol. 131
Leadership in the Future Experts’ Creativity Development with Scientific Research Activities 4 November 2014
Developing Deaf Children's Conceptual Understanding and Scientific Argumentation Skills: A Literature Review 3 January 2014 | Deafness & Education International, Vol. 16, No. 3
Leslie M. Stevens , and
Sally G. Hoskins
Nancy Pelaez, Monitoring Editor
Cortex, Vol. 51
A Sociotechnological Theory of Discursive Change and Entrepreneurial Capacity: Novelty and Networks SSRN Electronic Journal, Vol. 3
GEOverse: An Undergraduate Research Journal: Research Dissemination Within and Beyond the Curriculum 1 August 2013
Learning by Practice, High-Pressure Student Ateliers 2 August 2013
Relating Inter-Individual Differences in Verbal Creative Thinking to Cerebral Structures: An Optimal Voxel-Based Morphometry Study 5 November 2013 | PLoS ONE, Vol. 8, No. 11
21st Century Biology: An Interdisciplinary Approach of Biology, Technology, Engineering and Mathematics Education Procedia - Social and Behavioral Sciences, Vol. 102
Reclaiming creativity in the era of impact: exploring ideas about creative research in science and engineering Studies in Higher Education, Vol. 38, No. 9
An Evaluation of Alternative Ways of Computing the Creativity Quotient in a Design School Sample Creativity Research Journal, Vol. 25, No. 3
A.-M. Hoskinson ,
M. D. Caballero , and
J. K. Knight
Eric Brewe, Monitoring Editor
Understanding, attitude and environment International Journal for Researcher Development, Vol. 4, No. 1
Promoting Student Creativity and Inventiveness in Science and Engineering
Building creative thinking in the classroom: From research to practice International Journal of Educational Research, Vol. 62
A Demonstration of a Mastery Goal Driven Learning Environment to Foster Creativity in Engineering Design SSRN Electronic Journal, Vol. 111
The development of creative cognition across adolescence: distinct trajectories for insight and divergent thinking 8 October 2012 | Developmental Science, Vol. 16, No. 1
A CROSS-NATIONAL STUDY OF PROSPECTIVE ELEMENTARY AND SCIENCE TEACHERS’ CREATIVITY STYLES 10 September 2012 | Journal of Baltic Science Education, Vol. 11, No. 3
Evaluation of fostering students' creativity in preparing aided recalls for revision courses using electronic revision and recapitulation tools 2.0 Behaviour & Information Technology, Vol. 31, No. 8
Scientific Creativity: The Missing Ingredient in Slovenian Science Education 15 April 2012 | European Journal of Educational Research, Vol. volume-1-2012, No. volume1-issue2.html
Could the ‘evolution’ from biology to life sciences prevent ‘extinction’ of the subject field? 6 March 2012 | Suid-Afrikaanse Tydskrif vir Natuurwetenskap en Tegnologie, Vol. 31, No. 1
Mobile innovations, executive functions, and educational developments in conflict zones: a case study from Palestine 1 October 2011 | Educational Technology Research and Development, Vol. 60, No. 1
Informing Pedagogy Through the Brain-Targeted Teaching Model Journal of Microbiology & Biology Education, Vol. 13, No. 1
Teaching Creative Science Thinking Science, Vol. 334, No. 6062
Sally G. Hoskins ,
David Lopatto , and
Leslie M. Stevens
Diane K. O'Dowd, Monitoring Editor
Embedding Research-Based Learning Early in the Undergraduate Geography Curriculum Journal of Geography in Higher Education, Vol. 35, No. 3
Jared L. Taylor ,
Karen M. Smith ,
Adrian P. van Stolk , and
George B. Spiegelman
Debra Tomanek, Monitoring Editor
IFAC Proceedings Volumes, Vol. 43, No. 17
Critical and Creative Thinking Activities for Engaged Learning in Graphics and Visualization Course
Creativity Development through Inquiry-Based Learning in Biomedical Sciences

Submitted: 31 December 2008 Revised: 14 May 2009 Accepted: 28 May 2009

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Published: 11 January 2023

The effectiveness of collaborative problem solving in promoting students’ critical thinking: A meta-analysis based on empirical literature

Enwei Xu ORCID: orcid.org/0000-0001-6424-8169 1 ,
Wei Wang 1 &
Qingxia Wang 1

Humanities and Social Sciences Communications volume 10 , Article number: 16 ( 2023 ) Cite this article

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Science, technology and society

Collaborative problem-solving has been widely embraced in the classroom instruction of critical thinking, which is regarded as the core of curriculum reform based on key competencies in the field of education as well as a key competence for learners in the 21st century. However, the effectiveness of collaborative problem-solving in promoting students’ critical thinking remains uncertain. This current research presents the major findings of a meta-analysis of 36 pieces of the literature revealed in worldwide educational periodicals during the 21st century to identify the effectiveness of collaborative problem-solving in promoting students’ critical thinking and to determine, based on evidence, whether and to what extent collaborative problem solving can result in a rise or decrease in critical thinking. The findings show that (1) collaborative problem solving is an effective teaching approach to foster students’ critical thinking, with a significant overall effect size (ES = 0.82, z = 12.78, P < 0.01, 95% CI [0.69, 0.95]); (2) in respect to the dimensions of critical thinking, collaborative problem solving can significantly and successfully enhance students’ attitudinal tendencies (ES = 1.17, z = 7.62, P < 0.01, 95% CI[0.87, 1.47]); nevertheless, it falls short in terms of improving students’ cognitive skills, having only an upper-middle impact (ES = 0.70, z = 11.55, P < 0.01, 95% CI[0.58, 0.82]); and (3) the teaching type (chi 2 = 7.20, P < 0.05), intervention duration (chi 2 = 12.18, P < 0.01), subject area (chi 2 = 13.36, P < 0.05), group size (chi 2 = 8.77, P < 0.05), and learning scaffold (chi 2 = 9.03, P < 0.01) all have an impact on critical thinking, and they can be viewed as important moderating factors that affect how critical thinking develops. On the basis of these results, recommendations are made for further study and instruction to better support students’ critical thinking in the context of collaborative problem-solving.

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Introduction

Although critical thinking has a long history in research, the concept of critical thinking, which is regarded as an essential competence for learners in the 21st century, has recently attracted more attention from researchers and teaching practitioners (National Research Council, 2012 ). Critical thinking should be the core of curriculum reform based on key competencies in the field of education (Peng and Deng, 2017 ) because students with critical thinking can not only understand the meaning of knowledge but also effectively solve practical problems in real life even after knowledge is forgotten (Kek and Huijser, 2011 ). The definition of critical thinking is not universal (Ennis, 1989 ; Castle, 2009 ; Niu et al., 2013 ). In general, the definition of critical thinking is a self-aware and self-regulated thought process (Facione, 1990 ; Niu et al., 2013 ). It refers to the cognitive skills needed to interpret, analyze, synthesize, reason, and evaluate information as well as the attitudinal tendency to apply these abilities (Halpern, 2001 ). The view that critical thinking can be taught and learned through curriculum teaching has been widely supported by many researchers (e.g., Kuncel, 2011 ; Leng and Lu, 2020 ), leading to educators’ efforts to foster it among students. In the field of teaching practice, there are three types of courses for teaching critical thinking (Ennis, 1989 ). The first is an independent curriculum in which critical thinking is taught and cultivated without involving the knowledge of specific disciplines; the second is an integrated curriculum in which critical thinking is integrated into the teaching of other disciplines as a clear teaching goal; and the third is a mixed curriculum in which critical thinking is taught in parallel to the teaching of other disciplines for mixed teaching training. Furthermore, numerous measuring tools have been developed by researchers and educators to measure critical thinking in the context of teaching practice. These include standardized measurement tools, such as WGCTA, CCTST, CCTT, and CCTDI, which have been verified by repeated experiments and are considered effective and reliable by international scholars (Facione and Facione, 1992 ). In short, descriptions of critical thinking, including its two dimensions of attitudinal tendency and cognitive skills, different types of teaching courses, and standardized measurement tools provide a complex normative framework for understanding, teaching, and evaluating critical thinking.

Cultivating critical thinking in curriculum teaching can start with a problem, and one of the most popular critical thinking instructional approaches is problem-based learning (Liu et al., 2020 ). Duch et al. ( 2001 ) noted that problem-based learning in group collaboration is progressive active learning, which can improve students’ critical thinking and problem-solving skills. Collaborative problem-solving is the organic integration of collaborative learning and problem-based learning, which takes learners as the center of the learning process and uses problems with poor structure in real-world situations as the starting point for the learning process (Liang et al., 2017 ). Students learn the knowledge needed to solve problems in a collaborative group, reach a consensus on problems in the field, and form solutions through social cooperation methods, such as dialogue, interpretation, questioning, debate, negotiation, and reflection, thus promoting the development of learners’ domain knowledge and critical thinking (Cindy, 2004 ; Liang et al., 2017 ).

Collaborative problem-solving has been widely used in the teaching practice of critical thinking, and several studies have attempted to conduct a systematic review and meta-analysis of the empirical literature on critical thinking from various perspectives. However, little attention has been paid to the impact of collaborative problem-solving on critical thinking. Therefore, the best approach for developing and enhancing critical thinking throughout collaborative problem-solving is to examine how to implement critical thinking instruction; however, this issue is still unexplored, which means that many teachers are incapable of better instructing critical thinking (Leng and Lu, 2020 ; Niu et al., 2013 ). For example, Huber ( 2016 ) provided the meta-analysis findings of 71 publications on gaining critical thinking over various time frames in college with the aim of determining whether critical thinking was truly teachable. These authors found that learners significantly improve their critical thinking while in college and that critical thinking differs with factors such as teaching strategies, intervention duration, subject area, and teaching type. The usefulness of collaborative problem-solving in fostering students’ critical thinking, however, was not determined by this study, nor did it reveal whether there existed significant variations among the different elements. A meta-analysis of 31 pieces of educational literature was conducted by Liu et al. ( 2020 ) to assess the impact of problem-solving on college students’ critical thinking. These authors found that problem-solving could promote the development of critical thinking among college students and proposed establishing a reasonable group structure for problem-solving in a follow-up study to improve students’ critical thinking. Additionally, previous empirical studies have reached inconclusive and even contradictory conclusions about whether and to what extent collaborative problem-solving increases or decreases critical thinking levels. As an illustration, Yang et al. ( 2008 ) carried out an experiment on the integrated curriculum teaching of college students based on a web bulletin board with the goal of fostering participants’ critical thinking in the context of collaborative problem-solving. These authors’ research revealed that through sharing, debating, examining, and reflecting on various experiences and ideas, collaborative problem-solving can considerably enhance students’ critical thinking in real-life problem situations. In contrast, collaborative problem-solving had a positive impact on learners’ interaction and could improve learning interest and motivation but could not significantly improve students’ critical thinking when compared to traditional classroom teaching, according to research by Naber and Wyatt ( 2014 ) and Sendag and Odabasi ( 2009 ) on undergraduate and high school students, respectively.

The above studies show that there is inconsistency regarding the effectiveness of collaborative problem-solving in promoting students’ critical thinking. Therefore, it is essential to conduct a thorough and trustworthy review to detect and decide whether and to what degree collaborative problem-solving can result in a rise or decrease in critical thinking. Meta-analysis is a quantitative analysis approach that is utilized to examine quantitative data from various separate studies that are all focused on the same research topic. This approach characterizes the effectiveness of its impact by averaging the effect sizes of numerous qualitative studies in an effort to reduce the uncertainty brought on by independent research and produce more conclusive findings (Lipsey and Wilson, 2001 ).

This paper used a meta-analytic approach and carried out a meta-analysis to examine the effectiveness of collaborative problem-solving in promoting students’ critical thinking in order to make a contribution to both research and practice. The following research questions were addressed by this meta-analysis:

What is the overall effect size of collaborative problem-solving in promoting students’ critical thinking and its impact on the two dimensions of critical thinking (i.e., attitudinal tendency and cognitive skills)?

How are the disparities between the study conclusions impacted by various moderating variables if the impacts of various experimental designs in the included studies are heterogeneous?

This research followed the strict procedures (e.g., database searching, identification, screening, eligibility, merging, duplicate removal, and analysis of included studies) of Cooper’s ( 2010 ) proposed meta-analysis approach for examining quantitative data from various separate studies that are all focused on the same research topic. The relevant empirical research that appeared in worldwide educational periodicals within the 21st century was subjected to this meta-analysis using Rev-Man 5.4. The consistency of the data extracted separately by two researchers was tested using Cohen’s kappa coefficient, and a publication bias test and a heterogeneity test were run on the sample data to ascertain the quality of this meta-analysis.

Data sources and search strategies

There were three stages to the data collection process for this meta-analysis, as shown in Fig. 1 , which shows the number of articles included and eliminated during the selection process based on the statement and study eligibility criteria.

This flowchart shows the number of records identified, included and excluded in the article.

First, the databases used to systematically search for relevant articles were the journal papers of the Web of Science Core Collection and the Chinese Core source journal, as well as the Chinese Social Science Citation Index (CSSCI) source journal papers included in CNKI. These databases were selected because they are credible platforms that are sources of scholarly and peer-reviewed information with advanced search tools and contain literature relevant to the subject of our topic from reliable researchers and experts. The search string with the Boolean operator used in the Web of Science was “TS = (((“critical thinking” or “ct” and “pretest” or “posttest”) or (“critical thinking” or “ct” and “control group” or “quasi experiment” or “experiment”)) and (“collaboration” or “collaborative learning” or “CSCL”) and (“problem solving” or “problem-based learning” or “PBL”))”. The research area was “Education Educational Research”, and the search period was “January 1, 2000, to December 30, 2021”. A total of 412 papers were obtained. The search string with the Boolean operator used in the CNKI was “SU = (‘critical thinking’*‘collaboration’ + ‘critical thinking’*‘collaborative learning’ + ‘critical thinking’*‘CSCL’ + ‘critical thinking’*‘problem solving’ + ‘critical thinking’*‘problem-based learning’ + ‘critical thinking’*‘PBL’ + ‘critical thinking’*‘problem oriented’) AND FT = (‘experiment’ + ‘quasi experiment’ + ‘pretest’ + ‘posttest’ + ‘empirical study’)” (translated into Chinese when searching). A total of 56 studies were found throughout the search period of “January 2000 to December 2021”. From the databases, all duplicates and retractions were eliminated before exporting the references into Endnote, a program for managing bibliographic references. In all, 466 studies were found.

Second, the studies that matched the inclusion and exclusion criteria for the meta-analysis were chosen by two researchers after they had reviewed the abstracts and titles of the gathered articles, yielding a total of 126 studies.

Third, two researchers thoroughly reviewed each included article’s whole text in accordance with the inclusion and exclusion criteria. Meanwhile, a snowball search was performed using the references and citations of the included articles to ensure complete coverage of the articles. Ultimately, 36 articles were kept.

Two researchers worked together to carry out this entire process, and a consensus rate of almost 94.7% was reached after discussion and negotiation to clarify any emerging differences.

Eligibility criteria

Since not all the retrieved studies matched the criteria for this meta-analysis, eligibility criteria for both inclusion and exclusion were developed as follows:

The publication language of the included studies was limited to English and Chinese, and the full text could be obtained. Articles that did not meet the publication language and articles not published between 2000 and 2021 were excluded.

The research design of the included studies must be empirical and quantitative studies that can assess the effect of collaborative problem-solving on the development of critical thinking. Articles that could not identify the causal mechanisms by which collaborative problem-solving affects critical thinking, such as review articles and theoretical articles, were excluded.

The research method of the included studies must feature a randomized control experiment or a quasi-experiment, or a natural experiment, which have a higher degree of internal validity with strong experimental designs and can all plausibly provide evidence that critical thinking and collaborative problem-solving are causally related. Articles with non-experimental research methods, such as purely correlational or observational studies, were excluded.

The participants of the included studies were only students in school, including K-12 students and college students. Articles in which the participants were non-school students, such as social workers or adult learners, were excluded.

The research results of the included studies must mention definite signs that may be utilized to gauge critical thinking’s impact (e.g., sample size, mean value, or standard deviation). Articles that lacked specific measurement indicators for critical thinking and could not calculate the effect size were excluded.

Data coding design

In order to perform a meta-analysis, it is necessary to collect the most important information from the articles, codify that information’s properties, and convert descriptive data into quantitative data. Therefore, this study designed a data coding template (see Table 1 ). Ultimately, 16 coding fields were retained.

The designed data-coding template consisted of three pieces of information. Basic information about the papers was included in the descriptive information: the publishing year, author, serial number, and title of the paper.

The variable information for the experimental design had three variables: the independent variable (instruction method), the dependent variable (critical thinking), and the moderating variable (learning stage, teaching type, intervention duration, learning scaffold, group size, measuring tool, and subject area). Depending on the topic of this study, the intervention strategy, as the independent variable, was coded into collaborative and non-collaborative problem-solving. The dependent variable, critical thinking, was coded as a cognitive skill and an attitudinal tendency. And seven moderating variables were created by grouping and combining the experimental design variables discovered within the 36 studies (see Table 1 ), where learning stages were encoded as higher education, high school, middle school, and primary school or lower; teaching types were encoded as mixed courses, integrated courses, and independent courses; intervention durations were encoded as 0–1 weeks, 1–4 weeks, 4–12 weeks, and more than 12 weeks; group sizes were encoded as 2–3 persons, 4–6 persons, 7–10 persons, and more than 10 persons; learning scaffolds were encoded as teacher-supported learning scaffold, technique-supported learning scaffold, and resource-supported learning scaffold; measuring tools were encoded as standardized measurement tools (e.g., WGCTA, CCTT, CCTST, and CCTDI) and self-adapting measurement tools (e.g., modified or made by researchers); and subject areas were encoded according to the specific subjects used in the 36 included studies.

The data information contained three metrics for measuring critical thinking: sample size, average value, and standard deviation. It is vital to remember that studies with various experimental designs frequently adopt various formulas to determine the effect size. And this paper used Morris’ proposed standardized mean difference (SMD) calculation formula ( 2008 , p. 369; see Supplementary Table S3 ).

Procedure for extracting and coding data

According to the data coding template (see Table 1 ), the 36 papers’ information was retrieved by two researchers, who then entered them into Excel (see Supplementary Table S1 ). The results of each study were extracted separately in the data extraction procedure if an article contained numerous studies on critical thinking, or if a study assessed different critical thinking dimensions. For instance, Tiwari et al. ( 2010 ) used four time points, which were viewed as numerous different studies, to examine the outcomes of critical thinking, and Chen ( 2013 ) included the two outcome variables of attitudinal tendency and cognitive skills, which were regarded as two studies. After discussion and negotiation during data extraction, the two researchers’ consistency test coefficients were roughly 93.27%. Supplementary Table S2 details the key characteristics of the 36 included articles with 79 effect quantities, including descriptive information (e.g., the publishing year, author, serial number, and title of the paper), variable information (e.g., independent variables, dependent variables, and moderating variables), and data information (e.g., mean values, standard deviations, and sample size). Following that, testing for publication bias and heterogeneity was done on the sample data using the Rev-Man 5.4 software, and then the test results were used to conduct a meta-analysis.

Publication bias test

When the sample of studies included in a meta-analysis does not accurately reflect the general status of research on the relevant subject, publication bias is said to be exhibited in this research. The reliability and accuracy of the meta-analysis may be impacted by publication bias. Due to this, the meta-analysis needs to check the sample data for publication bias (Stewart et al., 2006 ). A popular method to check for publication bias is the funnel plot; and it is unlikely that there will be publishing bias when the data are equally dispersed on either side of the average effect size and targeted within the higher region. The data are equally dispersed within the higher portion of the efficient zone, consistent with the funnel plot connected with this analysis (see Fig. 2 ), indicating that publication bias is unlikely in this situation.

This funnel plot shows the result of publication bias of 79 effect quantities across 36 studies.

Heterogeneity test

To select the appropriate effect models for the meta-analysis, one might use the results of a heterogeneity test on the data effect sizes. In a meta-analysis, it is common practice to gauge the degree of data heterogeneity using the I 2 value, and I 2 ≥ 50% is typically understood to denote medium-high heterogeneity, which calls for the adoption of a random effect model; if not, a fixed effect model ought to be applied (Lipsey and Wilson, 2001 ). The findings of the heterogeneity test in this paper (see Table 2 ) revealed that I 2 was 86% and displayed significant heterogeneity ( P < 0.01). To ensure accuracy and reliability, the overall effect size ought to be calculated utilizing the random effect model.

The analysis of the overall effect size

This meta-analysis utilized a random effect model to examine 79 effect quantities from 36 studies after eliminating heterogeneity. In accordance with Cohen’s criterion (Cohen, 1992 ), it is abundantly clear from the analysis results, which are shown in the forest plot of the overall effect (see Fig. 3 ), that the cumulative impact size of cooperative problem-solving is 0.82, which is statistically significant ( z = 12.78, P < 0.01, 95% CI [0.69, 0.95]), and can encourage learners to practice critical thinking.

This forest plot shows the analysis result of the overall effect size across 36 studies.

In addition, this study examined two distinct dimensions of critical thinking to better understand the precise contributions that collaborative problem-solving makes to the growth of critical thinking. The findings (see Table 3 ) indicate that collaborative problem-solving improves cognitive skills (ES = 0.70) and attitudinal tendency (ES = 1.17), with significant intergroup differences (chi 2 = 7.95, P < 0.01). Although collaborative problem-solving improves both dimensions of critical thinking, it is essential to point out that the improvements in students’ attitudinal tendency are much more pronounced and have a significant comprehensive effect (ES = 1.17, z = 7.62, P < 0.01, 95% CI [0.87, 1.47]), whereas gains in learners’ cognitive skill are slightly improved and are just above average. (ES = 0.70, z = 11.55, P < 0.01, 95% CI [0.58, 0.82]).

The analysis of moderator effect size

The whole forest plot’s 79 effect quantities underwent a two-tailed test, which revealed significant heterogeneity ( I 2 = 86%, z = 12.78, P < 0.01), indicating differences between various effect sizes that may have been influenced by moderating factors other than sampling error. Therefore, exploring possible moderating factors that might produce considerable heterogeneity was done using subgroup analysis, such as the learning stage, learning scaffold, teaching type, group size, duration of the intervention, measuring tool, and the subject area included in the 36 experimental designs, in order to further explore the key factors that influence critical thinking. The findings (see Table 4 ) indicate that various moderating factors have advantageous effects on critical thinking. In this situation, the subject area (chi 2 = 13.36, P < 0.05), group size (chi 2 = 8.77, P < 0.05), intervention duration (chi 2 = 12.18, P < 0.01), learning scaffold (chi 2 = 9.03, P < 0.01), and teaching type (chi 2 = 7.20, P < 0.05) are all significant moderators that can be applied to support the cultivation of critical thinking. However, since the learning stage and the measuring tools did not significantly differ among intergroup (chi 2 = 3.15, P = 0.21 > 0.05, and chi 2 = 0.08, P = 0.78 > 0.05), we are unable to explain why these two factors are crucial in supporting the cultivation of critical thinking in the context of collaborative problem-solving. These are the precise outcomes, as follows:

Various learning stages influenced critical thinking positively, without significant intergroup differences (chi 2 = 3.15, P = 0.21 > 0.05). High school was first on the list of effect sizes (ES = 1.36, P < 0.01), then higher education (ES = 0.78, P < 0.01), and middle school (ES = 0.73, P < 0.01). These results show that, despite the learning stage’s beneficial influence on cultivating learners’ critical thinking, we are unable to explain why it is essential for cultivating critical thinking in the context of collaborative problem-solving.

Different teaching types had varying degrees of positive impact on critical thinking, with significant intergroup differences (chi 2 = 7.20, P < 0.05). The effect size was ranked as follows: mixed courses (ES = 1.34, P < 0.01), integrated courses (ES = 0.81, P < 0.01), and independent courses (ES = 0.27, P < 0.01). These results indicate that the most effective approach to cultivate critical thinking utilizing collaborative problem solving is through the teaching type of mixed courses.

Various intervention durations significantly improved critical thinking, and there were significant intergroup differences (chi 2 = 12.18, P < 0.01). The effect sizes related to this variable showed a tendency to increase with longer intervention durations. The improvement in critical thinking reached a significant level (ES = 0.85, P < 0.01) after more than 12 weeks of training. These findings indicate that the intervention duration and critical thinking’s impact are positively correlated, with a longer intervention duration having a greater effect.

Different learning scaffolds influenced critical thinking positively, with significant intergroup differences (chi 2 = 9.03, P < 0.01). The resource-supported learning scaffold (ES = 0.69, P < 0.01) acquired a medium-to-higher level of impact, the technique-supported learning scaffold (ES = 0.63, P < 0.01) also attained a medium-to-higher level of impact, and the teacher-supported learning scaffold (ES = 0.92, P < 0.01) displayed a high level of significant impact. These results show that the learning scaffold with teacher support has the greatest impact on cultivating critical thinking.

Various group sizes influenced critical thinking positively, and the intergroup differences were statistically significant (chi 2 = 8.77, P < 0.05). Critical thinking showed a general declining trend with increasing group size. The overall effect size of 2–3 people in this situation was the biggest (ES = 0.99, P < 0.01), and when the group size was greater than 7 people, the improvement in critical thinking was at the lower-middle level (ES < 0.5, P < 0.01). These results show that the impact on critical thinking is positively connected with group size, and as group size grows, so does the overall impact.

Various measuring tools influenced critical thinking positively, with significant intergroup differences (chi 2 = 0.08, P = 0.78 > 0.05). In this situation, the self-adapting measurement tools obtained an upper-medium level of effect (ES = 0.78), whereas the complete effect size of the standardized measurement tools was the largest, achieving a significant level of effect (ES = 0.84, P < 0.01). These results show that, despite the beneficial influence of the measuring tool on cultivating critical thinking, we are unable to explain why it is crucial in fostering the growth of critical thinking by utilizing the approach of collaborative problem-solving.

Different subject areas had a greater impact on critical thinking, and the intergroup differences were statistically significant (chi 2 = 13.36, P < 0.05). Mathematics had the greatest overall impact, achieving a significant level of effect (ES = 1.68, P < 0.01), followed by science (ES = 1.25, P < 0.01) and medical science (ES = 0.87, P < 0.01), both of which also achieved a significant level of effect. Programming technology was the least effective (ES = 0.39, P < 0.01), only having a medium-low degree of effect compared to education (ES = 0.72, P < 0.01) and other fields (such as language, art, and social sciences) (ES = 0.58, P < 0.01). These results suggest that scientific fields (e.g., mathematics, science) may be the most effective subject areas for cultivating critical thinking utilizing the approach of collaborative problem-solving.

The effectiveness of collaborative problem solving with regard to teaching critical thinking

According to this meta-analysis, using collaborative problem-solving as an intervention strategy in critical thinking teaching has a considerable amount of impact on cultivating learners’ critical thinking as a whole and has a favorable promotional effect on the two dimensions of critical thinking. According to certain studies, collaborative problem solving, the most frequently used critical thinking teaching strategy in curriculum instruction can considerably enhance students’ critical thinking (e.g., Liang et al., 2017 ; Liu et al., 2020 ; Cindy, 2004 ). This meta-analysis provides convergent data support for the above research views. Thus, the findings of this meta-analysis not only effectively address the first research query regarding the overall effect of cultivating critical thinking and its impact on the two dimensions of critical thinking (i.e., attitudinal tendency and cognitive skills) utilizing the approach of collaborative problem-solving, but also enhance our confidence in cultivating critical thinking by using collaborative problem-solving intervention approach in the context of classroom teaching.

Furthermore, the associated improvements in attitudinal tendency are much stronger, but the corresponding improvements in cognitive skill are only marginally better. According to certain studies, cognitive skill differs from the attitudinal tendency in classroom instruction; the cultivation and development of the former as a key ability is a process of gradual accumulation, while the latter as an attitude is affected by the context of the teaching situation (e.g., a novel and exciting teaching approach, challenging and rewarding tasks) (Halpern, 2001 ; Wei and Hong, 2022 ). Collaborative problem-solving as a teaching approach is exciting and interesting, as well as rewarding and challenging; because it takes the learners as the focus and examines problems with poor structure in real situations, and it can inspire students to fully realize their potential for problem-solving, which will significantly improve their attitudinal tendency toward solving problems (Liu et al., 2020 ). Similar to how collaborative problem-solving influences attitudinal tendency, attitudinal tendency impacts cognitive skill when attempting to solve a problem (Liu et al., 2020 ; Zhang et al., 2022 ), and stronger attitudinal tendencies are associated with improved learning achievement and cognitive ability in students (Sison, 2008 ; Zhang et al., 2022 ). It can be seen that the two specific dimensions of critical thinking as well as critical thinking as a whole are affected by collaborative problem-solving, and this study illuminates the nuanced links between cognitive skills and attitudinal tendencies with regard to these two dimensions of critical thinking. To fully develop students’ capacity for critical thinking, future empirical research should pay closer attention to cognitive skills.

The moderating effects of collaborative problem solving with regard to teaching critical thinking

In order to further explore the key factors that influence critical thinking, exploring possible moderating effects that might produce considerable heterogeneity was done using subgroup analysis. The findings show that the moderating factors, such as the teaching type, learning stage, group size, learning scaffold, duration of the intervention, measuring tool, and the subject area included in the 36 experimental designs, could all support the cultivation of collaborative problem-solving in critical thinking. Among them, the effect size differences between the learning stage and measuring tool are not significant, which does not explain why these two factors are crucial in supporting the cultivation of critical thinking utilizing the approach of collaborative problem-solving.

In terms of the learning stage, various learning stages influenced critical thinking positively without significant intergroup differences, indicating that we are unable to explain why it is crucial in fostering the growth of critical thinking.

Although high education accounts for 70.89% of all empirical studies performed by researchers, high school may be the appropriate learning stage to foster students’ critical thinking by utilizing the approach of collaborative problem-solving since it has the largest overall effect size. This phenomenon may be related to student’s cognitive development, which needs to be further studied in follow-up research.

With regard to teaching type, mixed course teaching may be the best teaching method to cultivate students’ critical thinking. Relevant studies have shown that in the actual teaching process if students are trained in thinking methods alone, the methods they learn are isolated and divorced from subject knowledge, which is not conducive to their transfer of thinking methods; therefore, if students’ thinking is trained only in subject teaching without systematic method training, it is challenging to apply to real-world circumstances (Ruggiero, 2012 ; Hu and Liu, 2015 ). Teaching critical thinking as mixed course teaching in parallel to other subject teachings can achieve the best effect on learners’ critical thinking, and explicit critical thinking instruction is more effective than less explicit critical thinking instruction (Bensley and Spero, 2014 ).

In terms of the intervention duration, with longer intervention times, the overall effect size shows an upward tendency. Thus, the intervention duration and critical thinking’s impact are positively correlated. Critical thinking, as a key competency for students in the 21st century, is difficult to get a meaningful improvement in a brief intervention duration. Instead, it could be developed over a lengthy period of time through consistent teaching and the progressive accumulation of knowledge (Halpern, 2001 ; Hu and Liu, 2015 ). Therefore, future empirical studies ought to take these restrictions into account throughout a longer period of critical thinking instruction.

With regard to group size, a group size of 2–3 persons has the highest effect size, and the comprehensive effect size decreases with increasing group size in general. This outcome is in line with some research findings; as an example, a group composed of two to four members is most appropriate for collaborative learning (Schellens and Valcke, 2006 ). However, the meta-analysis results also indicate that once the group size exceeds 7 people, small groups cannot produce better interaction and performance than large groups. This may be because the learning scaffolds of technique support, resource support, and teacher support improve the frequency and effectiveness of interaction among group members, and a collaborative group with more members may increase the diversity of views, which is helpful to cultivate critical thinking utilizing the approach of collaborative problem-solving.

With regard to the learning scaffold, the three different kinds of learning scaffolds can all enhance critical thinking. Among them, the teacher-supported learning scaffold has the largest overall effect size, demonstrating the interdependence of effective learning scaffolds and collaborative problem-solving. This outcome is in line with some research findings; as an example, a successful strategy is to encourage learners to collaborate, come up with solutions, and develop critical thinking skills by using learning scaffolds (Reiser, 2004 ; Xu et al., 2022 ); learning scaffolds can lower task complexity and unpleasant feelings while also enticing students to engage in learning activities (Wood et al., 2006 ); learning scaffolds are designed to assist students in using learning approaches more successfully to adapt the collaborative problem-solving process, and the teacher-supported learning scaffolds have the greatest influence on critical thinking in this process because they are more targeted, informative, and timely (Xu et al., 2022 ).

With respect to the measuring tool, despite the fact that standardized measurement tools (such as the WGCTA, CCTT, and CCTST) have been acknowledged as trustworthy and effective by worldwide experts, only 54.43% of the research included in this meta-analysis adopted them for assessment, and the results indicated no intergroup differences. These results suggest that not all teaching circumstances are appropriate for measuring critical thinking using standardized measurement tools. “The measuring tools for measuring thinking ability have limits in assessing learners in educational situations and should be adapted appropriately to accurately assess the changes in learners’ critical thinking.”, according to Simpson and Courtney ( 2002 , p. 91). As a result, in order to more fully and precisely gauge how learners’ critical thinking has evolved, we must properly modify standardized measuring tools based on collaborative problem-solving learning contexts.

With regard to the subject area, the comprehensive effect size of science departments (e.g., mathematics, science, medical science) is larger than that of language arts and social sciences. Some recent international education reforms have noted that critical thinking is a basic part of scientific literacy. Students with scientific literacy can prove the rationality of their judgment according to accurate evidence and reasonable standards when they face challenges or poorly structured problems (Kyndt et al., 2013 ), which makes critical thinking crucial for developing scientific understanding and applying this understanding to practical problem solving for problems related to science, technology, and society (Yore et al., 2007 ).

Suggestions for critical thinking teaching

Other than those stated in the discussion above, the following suggestions are offered for critical thinking instruction utilizing the approach of collaborative problem-solving.

First, teachers should put a special emphasis on the two core elements, which are collaboration and problem-solving, to design real problems based on collaborative situations. This meta-analysis provides evidence to support the view that collaborative problem-solving has a strong synergistic effect on promoting students’ critical thinking. Asking questions about real situations and allowing learners to take part in critical discussions on real problems during class instruction are key ways to teach critical thinking rather than simply reading speculative articles without practice (Mulnix, 2012 ). Furthermore, the improvement of students’ critical thinking is realized through cognitive conflict with other learners in the problem situation (Yang et al., 2008 ). Consequently, it is essential for teachers to put a special emphasis on the two core elements, which are collaboration and problem-solving, and design real problems and encourage students to discuss, negotiate, and argue based on collaborative problem-solving situations.

Second, teachers should design and implement mixed courses to cultivate learners’ critical thinking, utilizing the approach of collaborative problem-solving. Critical thinking can be taught through curriculum instruction (Kuncel, 2011 ; Leng and Lu, 2020 ), with the goal of cultivating learners’ critical thinking for flexible transfer and application in real problem-solving situations. This meta-analysis shows that mixed course teaching has a highly substantial impact on the cultivation and promotion of learners’ critical thinking. Therefore, teachers should design and implement mixed course teaching with real collaborative problem-solving situations in combination with the knowledge content of specific disciplines in conventional teaching, teach methods and strategies of critical thinking based on poorly structured problems to help students master critical thinking, and provide practical activities in which students can interact with each other to develop knowledge construction and critical thinking utilizing the approach of collaborative problem-solving.

Third, teachers should be more trained in critical thinking, particularly preservice teachers, and they also should be conscious of the ways in which teachers’ support for learning scaffolds can promote critical thinking. The learning scaffold supported by teachers had the greatest impact on learners’ critical thinking, in addition to being more directive, targeted, and timely (Wood et al., 2006 ). Critical thinking can only be effectively taught when teachers recognize the significance of critical thinking for students’ growth and use the proper approaches while designing instructional activities (Forawi, 2016 ). Therefore, with the intention of enabling teachers to create learning scaffolds to cultivate learners’ critical thinking utilizing the approach of collaborative problem solving, it is essential to concentrate on the teacher-supported learning scaffolds and enhance the instruction for teaching critical thinking to teachers, especially preservice teachers.

Implications and limitations

There are certain limitations in this meta-analysis, but future research can correct them. First, the search languages were restricted to English and Chinese, so it is possible that pertinent studies that were written in other languages were overlooked, resulting in an inadequate number of articles for review. Second, these data provided by the included studies are partially missing, such as whether teachers were trained in the theory and practice of critical thinking, the average age and gender of learners, and the differences in critical thinking among learners of various ages and genders. Third, as is typical for review articles, more studies were released while this meta-analysis was being done; therefore, it had a time limit. With the development of relevant research, future studies focusing on these issues are highly relevant and needed.

Conclusions

The subject of the magnitude of collaborative problem-solving’s impact on fostering students’ critical thinking, which received scant attention from other studies, was successfully addressed by this study. The question of the effectiveness of collaborative problem-solving in promoting students’ critical thinking was addressed in this study, which addressed a topic that had gotten little attention in earlier research. The following conclusions can be made:

Regarding the results obtained, collaborative problem solving is an effective teaching approach to foster learners’ critical thinking, with a significant overall effect size (ES = 0.82, z = 12.78, P < 0.01, 95% CI [0.69, 0.95]). With respect to the dimensions of critical thinking, collaborative problem-solving can significantly and effectively improve students’ attitudinal tendency, and the comprehensive effect is significant (ES = 1.17, z = 7.62, P < 0.01, 95% CI [0.87, 1.47]); nevertheless, it falls short in terms of improving students’ cognitive skills, having only an upper-middle impact (ES = 0.70, z = 11.55, P < 0.01, 95% CI [0.58, 0.82]).

As demonstrated by both the results and the discussion, there are varying degrees of beneficial effects on students’ critical thinking from all seven moderating factors, which were found across 36 studies. In this context, the teaching type (chi 2 = 7.20, P < 0.05), intervention duration (chi 2 = 12.18, P < 0.01), subject area (chi 2 = 13.36, P < 0.05), group size (chi 2 = 8.77, P < 0.05), and learning scaffold (chi 2 = 9.03, P < 0.01) all have a positive impact on critical thinking, and they can be viewed as important moderating factors that affect how critical thinking develops. Since the learning stage (chi 2 = 3.15, P = 0.21 > 0.05) and measuring tools (chi 2 = 0.08, P = 0.78 > 0.05) did not demonstrate any significant intergroup differences, we are unable to explain why these two factors are crucial in supporting the cultivation of critical thinking in the context of collaborative problem-solving.

Data availability

All data generated or analyzed during this study are included within the article and its supplementary information files, and the supplementary information files are available in the Dataverse repository: https://doi.org/10.7910/DVN/IPFJO6 .

Bensley DA, Spero RA (2014) Improving critical thinking skills and meta-cognitive monitoring through direct infusion. Think Skills Creat 12:55–68. https://doi.org/10.1016/j.tsc.2014.02.001

Article Google Scholar

Castle A (2009) Defining and assessing critical thinking skills for student radiographers. Radiography 15(1):70–76. https://doi.org/10.1016/j.radi.2007.10.007

Chen XD (2013) An empirical study on the influence of PBL teaching model on critical thinking ability of non-English majors. J PLA Foreign Lang College 36 (04):68–72

Google Scholar

Cohen A (1992) Antecedents of organizational commitment across occupational groups: a meta-analysis. J Organ Behav. https://doi.org/10.1002/job.4030130602

Cooper H (2010) Research synthesis and meta-analysis: a step-by-step approach, 4th edn. Sage, London, England

Cindy HS (2004) Problem-based learning: what and how do students learn? Educ Psychol Rev 51(1):31–39

Duch BJ, Gron SD, Allen DE (2001) The power of problem-based learning: a practical “how to” for teaching undergraduate courses in any discipline. Stylus Educ Sci 2:190–198

Ennis RH (1989) Critical thinking and subject specificity: clarification and needed research. Educ Res 18(3):4–10. https://doi.org/10.3102/0013189x018003004

Facione PA (1990) Critical thinking: a statement of expert consensus for purposes of educational assessment and instruction. Research findings and recommendations. Eric document reproduction service. https://eric.ed.gov/?id=ed315423

Facione PA, Facione NC (1992) The California Critical Thinking Dispositions Inventory (CCTDI) and the CCTDI test manual. California Academic Press, Millbrae, CA

Forawi SA (2016) Standard-based science education and critical thinking. Think Skills Creat 20:52–62. https://doi.org/10.1016/j.tsc.2016.02.005

Halpern DF (2001) Assessing the effectiveness of critical thinking instruction. J Gen Educ 50(4):270–286. https://doi.org/10.2307/27797889

Hu WP, Liu J (2015) Cultivation of pupils’ thinking ability: a five-year follow-up study. Psychol Behav Res 13(05):648–654. https://doi.org/10.3969/j.issn.1672-0628.2015.05.010

Huber K (2016) Does college teach critical thinking? A meta-analysis. Rev Educ Res 86(2):431–468. https://doi.org/10.3102/0034654315605917

Kek MYCA, Huijser H (2011) The power of problem-based learning in developing critical thinking skills: preparing students for tomorrow’s digital futures in today’s classrooms. High Educ Res Dev 30(3):329–341. https://doi.org/10.1080/07294360.2010.501074

Kuncel NR (2011) Measurement and meaning of critical thinking (Research report for the NRC 21st Century Skills Workshop). National Research Council, Washington, DC

Kyndt E, Raes E, Lismont B, Timmers F, Cascallar E, Dochy F (2013) A meta-analysis of the effects of face-to-face cooperative learning. Do recent studies falsify or verify earlier findings? Educ Res Rev 10(2):133–149. https://doi.org/10.1016/j.edurev.2013.02.002

Leng J, Lu XX (2020) Is critical thinking really teachable?—A meta-analysis based on 79 experimental or quasi experimental studies. Open Educ Res 26(06):110–118. https://doi.org/10.13966/j.cnki.kfjyyj.2020.06.011

Liang YZ, Zhu K, Zhao CL (2017) An empirical study on the depth of interaction promoted by collaborative problem solving learning activities. J E-educ Res 38(10):87–92. https://doi.org/10.13811/j.cnki.eer.2017.10.014

Lipsey M, Wilson D (2001) Practical meta-analysis. International Educational and Professional, London, pp. 92–160

Liu Z, Wu W, Jiang Q (2020) A study on the influence of problem based learning on college students’ critical thinking-based on a meta-analysis of 31 studies. Explor High Educ 03:43–49

Morris SB (2008) Estimating effect sizes from pretest-posttest-control group designs. Organ Res Methods 11(2):364–386. https://doi.org/10.1177/1094428106291059

Article ADS Google Scholar

Mulnix JW (2012) Thinking critically about critical thinking. Educ Philos Theory 44(5):464–479. https://doi.org/10.1111/j.1469-5812.2010.00673.x

Naber J, Wyatt TH (2014) The effect of reflective writing interventions on the critical thinking skills and dispositions of baccalaureate nursing students. Nurse Educ Today 34(1):67–72. https://doi.org/10.1016/j.nedt.2013.04.002

National Research Council (2012) Education for life and work: developing transferable knowledge and skills in the 21st century. The National Academies Press, Washington, DC

Niu L, Behar HLS, Garvan CW (2013) Do instructional interventions influence college students’ critical thinking skills? A meta-analysis. Educ Res Rev 9(12):114–128. https://doi.org/10.1016/j.edurev.2012.12.002

Peng ZM, Deng L (2017) Towards the core of education reform: cultivating critical thinking skills as the core of skills in the 21st century. Res Educ Dev 24:57–63. https://doi.org/10.14121/j.cnki.1008-3855.2017.24.011

Reiser BJ (2004) Scaffolding complex learning: the mechanisms of structuring and problematizing student work. J Learn Sci 13(3):273–304. https://doi.org/10.1207/s15327809jls1303_2

Ruggiero VR (2012) The art of thinking: a guide to critical and creative thought, 4th edn. Harper Collins College Publishers, New York

Schellens T, Valcke M (2006) Fostering knowledge construction in university students through asynchronous discussion groups. Comput Educ 46(4):349–370. https://doi.org/10.1016/j.compedu.2004.07.010

Sendag S, Odabasi HF (2009) Effects of an online problem based learning course on content knowledge acquisition and critical thinking skills. Comput Educ 53(1):132–141. https://doi.org/10.1016/j.compedu.2009.01.008

Sison R (2008) Investigating Pair Programming in a Software Engineering Course in an Asian Setting. 2008 15th Asia-Pacific Software Engineering Conference, pp. 325–331. https://doi.org/10.1109/APSEC.2008.61

Simpson E, Courtney M (2002) Critical thinking in nursing education: literature review. Mary Courtney 8(2):89–98

Stewart L, Tierney J, Burdett S (2006) Do systematic reviews based on individual patient data offer a means of circumventing biases associated with trial publications? Publication bias in meta-analysis. John Wiley and Sons Inc, New York, pp. 261–286

Tiwari A, Lai P, So M, Yuen K (2010) A comparison of the effects of problem-based learning and lecturing on the development of students’ critical thinking. Med Educ 40(6):547–554. https://doi.org/10.1111/j.1365-2929.2006.02481.x

Wood D, Bruner JS, Ross G (2006) The role of tutoring in problem solving. J Child Psychol Psychiatry 17(2):89–100. https://doi.org/10.1111/j.1469-7610.1976.tb00381.x

Wei T, Hong S (2022) The meaning and realization of teachable critical thinking. Educ Theory Practice 10:51–57

Xu EW, Wang W, Wang QX (2022) A meta-analysis of the effectiveness of programming teaching in promoting K-12 students’ computational thinking. Educ Inf Technol. https://doi.org/10.1007/s10639-022-11445-2

Yang YC, Newby T, Bill R (2008) Facilitating interactions through structured web-based bulletin boards: a quasi-experimental study on promoting learners’ critical thinking skills. Comput Educ 50(4):1572–1585. https://doi.org/10.1016/j.compedu.2007.04.006

Yore LD, Pimm D, Tuan HL (2007) The literacy component of mathematical and scientific literacy. Int J Sci Math Educ 5(4):559–589. https://doi.org/10.1007/s10763-007-9089-4

Zhang T, Zhang S, Gao QQ, Wang JH (2022) Research on the development of learners’ critical thinking in online peer review. Audio Visual Educ Res 6:53–60. https://doi.org/10.13811/j.cnki.eer.2022.06.08

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Acknowledgements

This research was supported by the graduate scientific research and innovation project of Xinjiang Uygur Autonomous Region named “Research on in-depth learning of high school information technology courses for the cultivation of computing thinking” (No. XJ2022G190) and the independent innovation fund project for doctoral students of the College of Educational Science of Xinjiang Normal University named “Research on project-based teaching of high school information technology courses from the perspective of discipline core literacy” (No. XJNUJKYA2003).

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Xu, E., Wang, W. & Wang, Q. The effectiveness of collaborative problem solving in promoting students’ critical thinking: A meta-analysis based on empirical literature. Humanit Soc Sci Commun 10 , 16 (2023). https://doi.org/10.1057/s41599-023-01508-1

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3 Simple Strategies to Improve Students’ Problem-Solving Skills

These strategies are designed to make sure students have a good understanding of problems before attempting to solve them.

Research provides a striking revelation about problem solvers. The best problem solvers approach problems much differently than novices. For instance, one meta-study showed that when experts evaluate graphs , they tend to spend less time on tasks and answer choices and more time on evaluating the axes’ labels and the relationships of variables within the graphs. In other words, they spend more time up front making sense of the data before moving to addressing the task.

While slower in solving problems, experts use this additional up-front time to more efficiently and effectively solve the problem. In one study, researchers found that experts were much better at “information extraction” or pulling the information they needed to solve the problem later in the problem than novices. This was due to the fact that they started a problem-solving process by evaluating specific assumptions within problems, asking predictive questions, and then comparing and contrasting their predictions with results. For example, expert problem solvers look at the problem context and ask a number of questions:

What do we know about the context of the problem?
What assumptions are underlying the problem? What’s the story here?
What qualitative and quantitative information is pertinent?
What might the problem context be telling us? What questions arise from the information we are reading or reviewing?
What are important trends and patterns?

As such, expert problem solvers don’t jump to the presented problem or rush to solutions. They invest the time necessary to make sense of the problem.

Now, think about your own students: Do they immediately jump to the question, or do they take time to understand the problem context? Do they identify the relevant variables, look for patterns, and then focus on the specific tasks?

If your students are struggling to develop the habit of sense-making in a problem- solving context, this is a perfect time to incorporate a few short and sharp strategies to support them.

3 Ways to Improve Student Problem-Solving

1. Slow reveal graphs: The brilliant strategy crafted by K–8 math specialist Jenna Laib and her colleagues provides teachers with an opportunity to gradually display complex graphical information and build students’ questioning, sense-making, and evaluating predictions.

For instance, in one third-grade class, students are given a bar graph without any labels or identifying information except for bars emerging from a horizontal line on the bottom of the slide. Over time, students learn about the categories on the x -axis (types of animals) and the quantities specified on the y -axis (number of baby teeth).

The graphs and the topics range in complexity from studying the standard deviation of temperatures in Antarctica to the use of scatterplots to compare working hours across OECD (Organization for Economic Cooperation and Development) countries. The website offers a number of graphs on Google Slides and suggests questions that teachers may ask students. Furthermore, this site allows teachers to search by type of graph (e.g., scatterplot) or topic (e.g., social justice).

2. Three reads: The three-reads strategy tasks students with evaluating a word problem in three different ways . First, students encounter a problem without having access to the question—for instance, “There are 20 kangaroos on the grassland. Three hop away.” Students are expected to discuss the context of the problem without emphasizing the quantities. For instance, a student may say, “We know that there are a total amount of kangaroos, and the total shrinks because some kangaroos hop away.”

Next, students discuss the important quantities and what questions may be generated. Finally, students receive and address the actual problem. Here they can both evaluate how close their predicted questions were from the actual questions and solve the actual problem.

To get started, consider using the numberless word problems on educator Brian Bushart’s site . For those teaching high school, consider using your own textbook word problems for this activity. Simply create three slides to present to students that include context (e.g., on the first slide state, “A salesman sold twice as much pears in the afternoon as in the morning”). The second slide would include quantities (e.g., “He sold 360 kilograms of pears”), and the third slide would include the actual question (e.g., “How many kilograms did he sell in the morning and how many in the afternoon?”). One additional suggestion for teams to consider is to have students solve the questions they generated before revealing the actual question.

3. Three-Act Tasks: Originally created by Dan Meyer, three-act tasks follow the three acts of a story . The first act is typically called the “setup,” followed by the “confrontation” and then the “resolution.”

This storyline process can be used in mathematics in which students encounter a contextual problem (e.g., a pool is being filled with soda). Here students work to identify the important aspects of the problem. During the second act, students build knowledge and skill to solve the problem (e.g., they learn how to calculate the volume of particular spaces). Finally, students solve the problem and evaluate their answers (e.g., how close were their calculations to the actual specifications of the pool and the amount of liquid that filled it).

Often, teachers add a fourth act (i.e., “the sequel”), in which students encounter a similar problem but in a different context (e.g., they have to estimate the volume of a lava lamp). There are also a number of elementary examples that have been developed by math teachers including GFletchy , which offers pre-kindergarten to middle school activities including counting squares , peas in a pod , and shark bait .

Students need to learn how to slow down and think through a problem context. The aforementioned strategies are quick ways teachers can begin to support students in developing the habits needed to effectively and efficiently tackle complex problem-solving.

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What Is Creative Problem-Solving & Why Is It Important?

Business team using creative problem-solving

01 Feb 2022

One of the biggest hindrances to innovation is complacency—it can be more comfortable to do what you know than venture into the unknown. Business leaders can overcome this barrier by mobilizing creative team members and providing space to innovate.

There are several tools you can use to encourage creativity in the workplace. Creative problem-solving is one of them, which facilitates the development of innovative solutions to difficult problems.

Here’s an overview of creative problem-solving and why it’s important in business.

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What Is Creative Problem-Solving?

Research is necessary when solving a problem. But there are situations where a problem’s specific cause is difficult to pinpoint. This can occur when there’s not enough time to narrow down the problem’s source or there are differing opinions about its root cause.

In such cases, you can use creative problem-solving , which allows you to explore potential solutions regardless of whether a problem has been defined.

Creative problem-solving is less structured than other innovation processes and encourages exploring open-ended solutions. It also focuses on developing new perspectives and fostering creativity in the workplace . Its benefits include:

Finding creative solutions to complex problems : User research can insufficiently illustrate a situation’s complexity. While other innovation processes rely on this information, creative problem-solving can yield solutions without it.
Adapting to change : Business is constantly changing, and business leaders need to adapt. Creative problem-solving helps overcome unforeseen challenges and find solutions to unconventional problems.
Fueling innovation and growth : In addition to solutions, creative problem-solving can spark innovative ideas that drive company growth. These ideas can lead to new product lines, services, or a modified operations structure that improves efficiency.

Design Thinking and Innovation | Uncover creative solutions to your business problems | Learn More

Creative problem-solving is traditionally based on the following key principles :

1. Balance Divergent and Convergent Thinking

Creative problem-solving uses two primary tools to find solutions: divergence and convergence. Divergence generates ideas in response to a problem, while convergence narrows them down to a shortlist. It balances these two practices and turns ideas into concrete solutions.

2. Reframe Problems as Questions

By framing problems as questions, you shift from focusing on obstacles to solutions. This provides the freedom to brainstorm potential ideas.

3. Defer Judgment of Ideas

When brainstorming, it can be natural to reject or accept ideas right away. Yet, immediate judgments interfere with the idea generation process. Even ideas that seem implausible can turn into outstanding innovations upon further exploration and development.

4. Focus on "Yes, And" Instead of "No, But"

Using negative words like "no" discourages creative thinking. Instead, use positive language to build and maintain an environment that fosters the development of creative and innovative ideas.

Creative Problem-Solving and Design Thinking

Whereas creative problem-solving facilitates developing innovative ideas through a less structured workflow, design thinking takes a far more organized approach.

Design thinking is a human-centered, solutions-based process that fosters the ideation and development of solutions. In the online course Design Thinking and Innovation , Harvard Business School Dean Srikant Datar leverages a four-phase framework to explain design thinking.

The four stages are:

The four stages of design thinking: clarify, ideate, develop, and implement

Clarify: The clarification stage allows you to empathize with the user and identify problems. Observations and insights are informed by thorough research. Findings are then reframed as problem statements or questions.
Ideate: Ideation is the process of coming up with innovative ideas. The divergence of ideas involved with creative problem-solving is a major focus.
Develop: In the development stage, ideas evolve into experiments and tests. Ideas converge and are explored through prototyping and open critique.
Implement: Implementation involves continuing to test and experiment to refine the solution and encourage its adoption.

Creative problem-solving primarily operates in the ideate phase of design thinking but can be applied to others. This is because design thinking is an iterative process that moves between the stages as ideas are generated and pursued. This is normal and encouraged, as innovation requires exploring multiple ideas.

Creative Problem-Solving Tools

While there are many useful tools in the creative problem-solving process, here are three you should know:

Creating a Problem Story

One way to innovate is by creating a story about a problem to understand how it affects users and what solutions best fit their needs. Here are the steps you need to take to use this tool properly.

1. Identify a UDP

Create a problem story to identify the undesired phenomena (UDP). For example, consider a company that produces printers that overheat. In this case, the UDP is "our printers overheat."

2. Move Forward in Time

To move forward in time, ask: “Why is this a problem?” For example, minor damage could be one result of the machines overheating. In more extreme cases, printers may catch fire. Don't be afraid to create multiple problem stories if you think of more than one UDP.

3. Move Backward in Time

To move backward in time, ask: “What caused this UDP?” If you can't identify the root problem, think about what typically causes the UDP to occur. For the overheating printers, overuse could be a cause.

Following the three-step framework above helps illustrate a clear problem story:

The printer is overused.
The printer overheats.
The printer breaks down.

You can extend the problem story in either direction if you think of additional cause-and-effect relationships.

4. Break the Chains

By this point, you’ll have multiple UDP storylines. Take two that are similar and focus on breaking the chains connecting them. This can be accomplished through inversion or neutralization.

Inversion: Inversion changes the relationship between two UDPs so the cause is the same but the effect is the opposite. For example, if the UDP is "the more X happens, the more likely Y is to happen," inversion changes the equation to "the more X happens, the less likely Y is to happen." Using the printer example, inversion would consider: "What if the more a printer is used, the less likely it’s going to overheat?" Innovation requires an open mind. Just because a solution initially seems unlikely doesn't mean it can't be pursued further or spark additional ideas.
Neutralization: Neutralization completely eliminates the cause-and-effect relationship between X and Y. This changes the above equation to "the more or less X happens has no effect on Y." In the case of the printers, neutralization would rephrase the relationship to "the more or less a printer is used has no effect on whether it overheats."

Even if creating a problem story doesn't provide a solution, it can offer useful context to users’ problems and additional ideas to be explored. Given that divergence is one of the fundamental practices of creative problem-solving, it’s a good idea to incorporate it into each tool you use.

Brainstorming

Brainstorming is a tool that can be highly effective when guided by the iterative qualities of the design thinking process. It involves openly discussing and debating ideas and topics in a group setting. This facilitates idea generation and exploration as different team members consider the same concept from multiple perspectives.

Hosting brainstorming sessions can result in problems, such as groupthink or social loafing. To combat this, leverage a three-step brainstorming method involving divergence and convergence :

Have each group member come up with as many ideas as possible and write them down to ensure the brainstorming session is productive.
Continue the divergence of ideas by collectively sharing and exploring each idea as a group. The goal is to create a setting where new ideas are inspired by open discussion.
Begin the convergence of ideas by narrowing them down to a few explorable options. There’s no "right number of ideas." Don't be afraid to consider exploring all of them, as long as you have the resources to do so.

Alternate Worlds

The alternate worlds tool is an empathetic approach to creative problem-solving. It encourages you to consider how someone in another world would approach your situation.

For example, if you’re concerned that the printers you produce overheat and catch fire, consider how a different industry would approach the problem. How would an automotive expert solve it? How would a firefighter?

Be creative as you consider and research alternate worlds. The purpose is not to nail down a solution right away but to continue the ideation process through diverging and exploring ideas.

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Continue Developing Your Skills

Whether you’re an entrepreneur, marketer, or business leader, learning the ropes of design thinking can be an effective way to build your skills and foster creativity and innovation in any setting.

If you're ready to develop your design thinking and creative problem-solving skills, explore Design Thinking and Innovation , one of our online entrepreneurship and innovation courses. If you aren't sure which course is the right fit, download our free course flowchart to determine which best aligns with your goals.

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Home Courses Creativity and Soft Skills Boosting Creative Thinking and Problem Solving

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Contemporary education increasingly focuses on teaching how to generate new ideas and critically address problems . Accordingly, creativity is quickly taking hold in the educational domain. Yet, it remains subject to serious misconceptions, which consider it as the stroke of genius of gifted individuals, or as an innate capacity.

The course will challenge these conceptions by illustrating many strategies to nurture, train, and ultimately improve creativity. By its end, participants will be convinced that creativity implies tinkering with tools, assessing the results, making tweaks, and ultimately visualizing the idea emerging from this endeavor.

Participants will practice many methods to generate new ideas across a variety of tasks and domains. By focusing on how creative thinking works rather than seeing it as an outcome, they will realize that creative thinking is a process that can be scaffolded by tools and external structures.

Course participants will learn to use some of the most famous tools in the field of innovation to boost creative thinking. They will discover different techniques to scaffold problem-solving, come up with new solutions, create stories and narratives, nurture imagination, and visualize non-existing realities.

Moreover, they will devolve time to experiment with these techniques in idea generation, storytelling, as well as concept art.

Participants will also learn how to lead their students to adopt these tools as an individual practice as well as a collective process during daily classroom interactions.

Hitting the new challenges raised by our society, not only the course will help participants embed creativity in the curriculum, but it will also nurture their students with a new way of thinking, addressing problems, and creating solutions.

Besides being at the core of rapidly growing disciplines – such as design, communication, technology development, and the arts – acquiring these abilities will also crucially scaffold students’ intellectual and personal development.

What is included

Unmatched Support : 18-hour daily chat assistance

Fully Fundable : tailored on Erasmus+ budgets

Flexibility Guaranteed : easy changes with minimal restrictions

360° experience : from coffee breaks to cultural visits

Post-Course Growth : 100€ online course voucher

Learning outcomes

The course will help the participants to:

Understand the characteristics of creative thinking;
Learn to use creative tools across multiple situations and fields through activities and exercises;
Nurture students in using creative thinking strategies for their personal and professional growth;
Embed creativity into the students’ curriculum and classroom practices;
Grasp the aspects shared by creative methodologies in different domains.

Tentative schedule

Day 1 – what is creative thinking.

Introduction to the course, the school, and the external week activities;
Icebreaker activities;
Presentations of the participants’ schools;
Setting out the participants’ needs and objectives;
“That time I had a stroke of genius” vs. Reality;
Tinkering with thinking;
Course main goal: teaching students to think differently.

Day 2 – Problem-solving and idea-generation

Brainstorming;
Brainwriting;
Mindmapping;
Random words;
How can these tools be used in teachers’ daily activities?

Day 3 – Storytelling

The principles of storytelling;
Fabula cards;

Day 4 – Concept Art

Intro to concept art;
Imagining the unseen;
Epistemic drawings;
Reference raiding;
Visual libraries;
Ideation through Iteration;
Visual Tinkering;

Day 5 – Tinker thinking for education

Comparing creative tools from different domains;
Assessing differences and commonalities;
Assessing how to exploit them in the participant educational systems.

Day 6 – Course closure & cultural activities

Course evaluation: round-up of acquired competencies, feedback, and discussion;
Awarding of the course Certificate of Attendance;
Excursion and other external cultural activities.

Confirmed sessions

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Dates and locations

= confirmed date

22-27 Apr 2024
27 May - 1 Jun 2024
24-29 Jun 2024
22-27 Jul 2024
26-31 Aug 2024
23-28 Sep 2024
28 Oct - 2 Nov 2024
25-30 Nov 2024
27 Jan - 1 Feb 2025
24 Feb - 1 Mar 2025
24-29 Mar 2025

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Amsterdam, Netherlands

Cultural Activities

A walking tour One excursion on Saturday

8-13 Apr 2024
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Ghent, Belgium

Ghent’s 48h city card

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Prague, Czech Republic

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Creative Problem Solving And Its Techniques

Entrepreneurs need to script their own journeys, figure out their own things, and solve problems. If you keep running back…

Entrepreneurs need to script their own journeys, figure out their own things, and solve problems. If you keep running back to your mentor at the drop of your hat, you’re not an entrepreneur. A true entrepreneur is a risk-taker, problem-solver, a person who’s willing to face challenges and failures.

– Kiran Mazumdar-Shaw, chairperson, and MD of Biocon

While scripting your own life and career journey, it is imperative to master the skill of creative problem-solving. Successful people and organizations recognize that the solutions to their problems lie within themselves. They try to find them with a creative problem-solving process.

Most professionals face problems at work. It could be meeting a sales target or fixing a technical glitch in a product. Learning how to solve problems efficiently is a key skill for success at work and life in general. Sometimes, you have to think out of the box to solve problems creatively.

What is creative problem-solving?

Have you noticed how some people have a knack for turning a problem into an opportunity? Take the stones people throw at you and use them to build a monument, said former Tata Group chairman Ratan Tata. It was a fantastic way of expressing creative problem-solving at work.

Creative problem-solving involves approaching a problem or a challenge in an inventive way. It is a process that redefines problems and opportunities and helps us come up with innovative solutions.

Generally, the creative problem-solving process involves the following stages:

Identify the problem or the challenge

Generate ideas that may be possible solutions

Solve the problem with the help of generated ideas

Implement the solution plan and move to the next step

A well-planned and strategically executed creative problem-solving process brings team members together. It encourages proactive participation among colleagues.

Let’s look at an example. Seema was not happy with her career in the IT industry. She approached the problem by thinking about various options that appealed to her. Using her creative problem-solving skill, she decided to try her hand at travel blogging given her passion for travel and nose for digital marketing.

Let’s turn to some highly successful techniques of creative problem-solving.

Techniques of creative problem-solving

1. brainstorming.

Brainstorming is one of the most popular techniques of creative problem-solving. It is an individual as well as a group activity. When the city’s municipal corporation needs to come up with measures regarding safety and health, citizens are often asked to brainstorm and suggest innovative ideas. Brainstorming is a blend of creativity and problem-solving.

2. Mind-mapping

Mind-mapping is a useful creative problem-solving process. A mind map is a graphic representation of ideas and concepts. It is a visual tool for creativity and problem-solving. Mind maps help you categorize and structure information. They aid comprehension, analysis, and help generate innovative ideas. Seeing the problem and possible solutions represented in visual form helps many of us see the bigger picture and connect the dots.

3. Counterfactual Thinking

When Rosie has to take a call on a problem, she thinks about all her previous decisions. She thinks of the things that have gone wrong and the opportunities that she missed out on. Such counterfactual thinking helps her face the current problem and find a solution. Counterfactual thinking is one of the smartest examples of creative problem-solving at work. However, it is important not to channel negative emotions while going down the counterfactual thinking route. Use your past experiences to ensure you don’t repeat mistakes, seize opportunities, and measure how far you’ve come. Be present and future-focused, and don’t use counterfactual thoughts to get trapped in the “What ifs” of your past.

4. Abstraction

Abstraction is a great booster for creativity and problem-solving. When a creative director in an advertising agency has to design a campaign for a brand of fruit drinks or evening wear, he uses abstraction. He thinks about the emotions associated with the drink or the evening, such as camaraderie, romance, taste, health, joy, and so on. ( xanax )

You must have noticed many examples of creative problem-solving at work.

Deploying a thought experiment by using comparison or similarity as a tool

Breaking free from assumptions to think originally

Going beyond assigned tasks to experiment

Raising questions and seeking new viewpoints

Reapplying rules that have worked previously

Stepping out of your comfort zone and thinking differently

Go ahead and build a culture of creativity around you. Overcome your mental barriers and let your imagination run free. Navigate obstacles to solve problems and come up with innovative solutions.

Harappa Education’s Unleashing Creativity course teaches you how to generate, test, and refine new ideas. It empowers you with in-depth creativity and problem-solving skills by teaching you concepts such as the Disney Creative Tool framework involving three roles: including dreamers, realists, and critics. Assigning these roles to groups will help organizations brainstorm ideas, create plans, and identify roadblocks. to reach the desired goals successfully. Sign up and begin your creative problem-solving journey.

Explore topics such as Creative Thinking & How to be Creative at Work from our Harappa Diaries blog section and develop your strategic thinking skills .

Education | Thompson School District students solve…

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Education | thompson school district students solve problems with a head full of steam, destination imagination clubs across the district excelled at creative problem solving tasks, advance to state tournament.

Destination Imagination team members from Cottonwood Plains Elementary School pose for a photo Thursday, cheering about their first place win in their category during the regional Destination Imagination competition. Clockwise from bottom left are Camden Headley, 9, Oscar Lyoa, 8, Zoe Nava, 8, Genesis Aceviz, 9, Cora Meuli, 9, Victoria Baylon, 8, and Javier Gomez, 8. The wolf picture with them was the inspiration for the play they created for the competition. (Jenny Sparks/Loveland Reporter-Herald)

Students in several of the Thompson School District’s Destination Imagination clubs performed well enough in a regional competition earlier this month to qualify for the state tournament in early April.

Destination Imagination focuses on solving problems related to STEAM (Science, Technology, Engineering, Art and Math). The acronym might be more recognizable in its previous form, STEM, which omitted the arts.

LOVELAND, CO - MARCH 28, 2024: Destination Imagination team members perform the play Thursday, March 28, 2024, they created for their Destination Imagination competition. They won first place in their category during the regional destination imagination competition and qulaified for the state tournament. From left are Victoria Baylon (on the floor), Camden Headley, 9, Cora Meuli, 9, OScar Loya, 8, Javier Gomez, 8, Zoe Nava, 8, and Genesis Aceviz, 9. (Jenny Sparks/Loveland Reporter-Herald)

But the arts are a big part of Destination Imagination, or DI as it’s sometimes called by its participants.

For instance, one of TSD’s winning teams, a group of third graders at Cottonwood Plains Elementary School, won first place in their category earlier this month for a play they wrote and performed entirely in Spanish.

Cottonwood Plains is a bilingual school, which enables it to accommodate native Spanish speakers and English speakers with an interest in learning a second language at a young age.

The Cottonwood Plains team includes both: Some speak Spanish at home and others English. Some have parents that don’t speak English. Others have parents that don’t speak Spanish, and some have bilingual households.

But the seven third graders on the team are all capable of performing in Spanish and subsequently answering judges’ questions in English, or vice versa, regardless of their first language.

Crucial to the program is the agency of the students.

Teachers and parents serve as coaches, but they are largely absent from the actual creative process, other than asking questions of the students.

At Cottonwood Plains, coaches Yesenia Perez and Belen Lopez provided direction to their students, but the third graders made all of the decisions, from the plot of their play, which followed the story of two wolf statues deciding whether to turn into real wolves, to the sets and costumes.

“They do the whole thing,” Lopez said.

More remarkable still was the time frame with which students across TSD pulled together their projects. The district was delayed in getting the club off the ground until after winter break, while other school districts managed to start in the fall.

“We came back from school, we had to meet with the parents, the parents had to say yes, we had to arrange everything,” Perez said. “So we had five weeks.”

Another group at Truscott Elementary chose an engineering project as their challenge, and constructed a giant pinball machine out of a piece of plywood the size of a twin-sized bed and a soccer ball, with obstacles made of Solo Cups and PVC pipe.

Even choosing the projects is the domain of students. At Truscott, what challenge to pursue was decided by each student writing their preference down on a piece of paper that was placed into a hat, and then drawing out one of the entries.

A performance element is required of all projects, even the engineering and math heavy ones, so Truscott students elected for a narrative involving the Teenage Mutant Ninja Turtles defending their pinball machine from a villain who wanted to use it.

The villain was the brainchild of fourth grader Frankie Dickson: a salad. Her reasoning was simple.

“Because the turtles love pizza,” Dickson said. “The enemy of pizza is salad.”

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Thompson School District students had the opportunity to shadow Superintendent Marc Schaffer and members of his cabinet Wednesday, offering them a glimpse into the inner workings of the school district while also giving officials like Schaffer a chance to hear students’ feedback and to, in Schaffer’s words, reflect on what can sometimes become routine.

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VIDEO

Funny Mathematical Problem Solving
Creative Problem Solving Unconventional Approaches to Success
Creative Problem-Solving: Innovation in Action
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Creative Problem Solving Chapter 4
Creative Problem Solving Chapter 7

COMMENTS

PDF Creative Problem Solving
CPS is a comprehensive system built on our own natural thinking processes that deliberately ignites creative thinking and produces innovative solutions. Through alternating phases of divergent and convergent thinking, CPS provides a process for managing thinking and action, while avoiding premature or inappropriate judgment. It is built upon a ...
What is CPS?
S. olving. CPS is a proven method for approaching a problem or a challenge in an imaginative and innovative way. It helps you redefine the problems and opportunities you face, come up with new, innovative responses and solutions, and then take action. If you search the Internet for "Creative Problem Solving," you'll find many variations ...
Creative problem solving tools and skills for students and teachers
So, in this case, it may be beneficial to teach the individual parts of the process in isolation first. 1. Clarify: Before beginning to seek creative solutions to a problem, it is important to clarify the exact nature of that problem. To do this, students should do the following three things: i. Identify the Problem.
PDF CEF
Why Creative Problem Solving (CPS)? Mastery of Creative Problem Solving as a practice equips you to: • Create an environment in which creativity and innovation thrive. • Use a broad set of tools and methods to foster key behaviors conducive to creative thinking. • Engage personal, organizational, and social benefits of CPS.
Get Started with Design Thinking
Design thinking is a methodology for creative problem solving. You can use it to inform your own teaching practice, or you can teach it to your students as a framework for real-world projects. The set of resources on this page offer experiences and lessons you can run with your students. This gives educators interested in teaching design ...
Creative Education Foundation
For more than 65 years, Creative Education Foundation (CEF) has been teaching adults and children in organizations, schools, and communities how to use the proven Creative Problem Solving process to develop new ideas, solve problems, and implement solutions.In 1954, Alex Osborn - legendary advertising executive, coiner of the term "brainstorming", and author of the ground-breaking book ...
Creative Problem Solving
About Creative Problem Solving. Alex Osborn, founder of the Creative Education Foundation, first developed creative problem solving in the 1940s, along with the term "brainstorming." And, together with Sid Parnes, he developed the Osborn-Parnes Creative Problem Solving Process. Despite its age, this model remains a valuable approach to problem ...
Creative Problem Solving: The History, Development, and Implications
This article presents a summary of research, development, and applications of Creative Problem Solving (CPS) in educational settings and, more specifically, in gifted education. The CPS framework is widely known and applied as one important goal in contemporary gifted education, as well as in relation to initiatives for "teaching thinking ...
Developing students' creative problem solving skills with ...
2.2 Creative problem solving and STEM education. The creative problem solving technique is one of the problem solving types. This technique was first used with the brainstorming technique introduced by Alex Osborn in the 1930s (Isaksen & Treffinger, 2004). Creative problem solving has been studied and reconstructed by researchers and each ...
Creative Problem Solving
The PISA 2012 Creative Problem Solvingassessment advanced large-scale, competency-based assessment beyond the traditional scope of literacy and numeracy. It focused on the general cognitive processes involved in problem solving, rather than on students' ability to solve problems in particular school subjects.
Creative Problem Solving in Primary Education ...
1. Introduction. Modern society requires people to be able to solve problems in a creative way (Craft, 2011).As such, educational systems need to produce creative problem solvers that try to understand everyday challenges, generate multiple creative ideas and select the most creative ideas to put into practice (Isaksen, Dorval, & Treffinger, 2011).An idea is seen as creative when it is ...
Creative Problem-Solving
Humans are innate creative problem-solvers. Since early humans developed the first stone tools to crack open fruit and nuts more than 2 million years ago, the application of creative thinking to solve problems has been a distinct competitive advantage for our species (Puccio 2017).Originally used to solve problems related to survival, the tendency toward the use of creative problem-solving to ...
Teaching Creativity and Inventive Problem Solving in Science
Abstract. Engaging learners in the excitement of science, helping them discover the value of evidence-based reasoning and higher-order cognitive skills, and teaching them to become creative problem solvers have long been goals of science education reformers. But the means to achieve these goals, especially methods to promote creative thinking ...
Supporting creative problem solving in primary geometry education
Supporting creative problem solving in primary geometry education. This intervention study aimed to identify how creative thinking can be supported in geometry education. Fifth-graders received five geometry lessons that incorporated divergent and convergent thinking. Children were assigned to a condition with either no creative thinking ...
Center for Creative Learning: Creative Problem Solving (CPS), talent
Our Creative Problem Solving (CPS) model will help you prepare creative and critical thinkers. CPS enables individuals and groups to manage change and deal successfully with complex, open-ended challenges. ... The LoS model guides you in meeting the needs of high ability students across many talent areas and in blending gifted education with ...
Creative problem solving in knowledge-rich contexts
Creative problem solving (CPS) relies on the reorganization of existing knowledge to serve new, problem-relevant functions. ... Better understanding of CPS as a process, especially via analogical transfer, has timely potential to inform education and creativity training. Creative problem solving (CPS) in real-world contexts often relies on ...
The effectiveness of collaborative problem solving in promoting
Collaborative problem-solving has been widely embraced in the classroom instruction of critical thinking, which is regarded as the core of curriculum reform based on key competencies in the field ...
3 Ways to Improve Student Problem-Solving
While slower in solving problems, experts use this additional up-front time to more efficiently and effectively solve the problem. In one study, researchers found that experts were much better at "information extraction" or pulling the information they needed to solve the problem later in the problem than novices. This was due to the fact that they started a problem-solving process by ...
CPS for Educators
Creative Problem Solving (CPS) unlocks creative thinking and teaches critical thinking processes that transform creativity into action. The CPS process also builds confidence, resilience, and tolerance for ambiguity because once learned, students know that whatever they face, they have clear steps to apply to get through any challenge. CEF ...
What Is Creative Problem-Solving & Why Is It Important?
Its benefits include: Finding creative solutions to complex problems: User research can insufficiently illustrate a situation's complexity. While other innovation processes rely on this information, creative problem-solving can yield solutions without it. Adapting to change: Business is constantly changing, and business leaders need to adapt.
PDF Enhancing Creative Problem Solving in Postgraduate Courses of Education
develop these problem-solving skills (Visone, 2018). Hence, it is essential for education management to focus on advancing postgraduates' problem-solving ability to support the future workforce (Chen et al., 2020). Professional problem solvers are receiving new requests in relation to creative problem solving (CPS) connected to
PDF Creative Problem-Solving and Creativity Product in STEM Education
It comprises 1) ask, 2) research, 3) imagine, 4) plan, 5) create, 6) test, and 7) improve. 2. The creative problem-solving ability. This is defined as the ability to find answers for problems or distinctive approaches to solving problems that yield more effective outcomes than other approaches.
10 Creative Problem-Solving Techniques You Need to Try Today
Creative problem-solving techniques can help you to overcome difficult challenges and unlock your inner genius. By exploring a variety of different techniques, such as brainstorming, mind mapping, and the SCAMPER method, you can approach problems from new angles and discover innovative solutions.
Enhance Creative Problem-Solving with Online Education
Creative problem solving is an invaluable skill that you can refine and enhance through a plethora of online resources. Whether you're looking to tackle complex challenges in your personal life ...
Boosting Creative Thinking and Problem Solving
Description . Contemporary education increasingly focuses on teaching how to generate new ideas and critically address problems.Accordingly, creativity is quickly taking hold in the educational domain. Yet, it remains subject to serious misconceptions, which consider it as the stroke of genius of gifted individuals, or as an innate capacity.
Creative Problem Solving And Its Techniques
2. Mind-mapping. Mind-mapping is a useful creative problem-solving process. A mind map is a graphic representation of ideas and concepts. It is a visual tool for creativity and problem-solving. Mind maps help you categorize and structure information. They aid comprehension, analysis, and help generate innovative ideas.
CPSI
Whether you are new to deliberate creativity or a seasoned creativity professional, CPSI provides an array of engaging, transformative, and easy to apply creativity, innovation, and leadership skills. New attendees learn from our hand selected and trained Core CPS Faculty, by participating in our Core CPS Courses. Returning attendees can choose ...
Thompson School District students solve problems with a head full of
Thompson School District students solve problems with a head full of STEAM Destination Imagination clubs across the district excelled at creative problem solving tasks, advance to state tournament

Creative Problem Solving

About Creative Problem Solving

Why Use Creative Problem Solving?

Core Principles of Creative Problem Solving

How to Use the Tool

Figure 1 – CPS Learner's Model

Explore the Vision

Gather Data

Formulate Questions

Explore Ideas

Formulate Solutions

4. Implement

Creative Problem Solving (CPS) Infographic

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Teaching Creativity and Inventive Problem Solving in Science

INTRODUCTION

What Is Creativity? Big-C versus Mini-C Creativity

Creativity Is a Multicomponent Process

Creativity Is Widely Distributed and Occurs in a Social Context

LITERATURE REVIEW

Promoting Creative Problem Solving in the College Classroom

How Is Creativity Related to Critical Thinking and the Higher-Order Cognitive Skills?

Assessment of Creativity

SCIENTIFIC TEACHING TO PROMOTE CREATIVITY

Creative Problem Solving

Talent Development

Problem Solving Styles

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TALENT DEVELOPMENT

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The effectiveness of collaborative problem solving in promoting students’ critical thinking: A meta-analysis based on empirical literature

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