Research

PhET conducts research on both the design and use of interactive simulations to better understand:

Which characteristics make these tools effective for learning and why
How students engage and interact with these tools to learn, and what influences this process
When, how, and why these tools are effective in a variety of learning environments

The PhET simulation design principles are based on research on how students learn (Bransford et al., 2000) and from our simulation interviews (see PhET Design Process). Between four and six think-aloud style interviews with individual students are done with each simulation. These interviews provide a rich data source for studying interface design and student learning. The PhET Look and Feel briefly describes our interface design principles and a complete discussion is found in the pair of papers by Adams et al., 2008.

Bransford, J.D., Brown, A. L. And Cocking, R. R. (2000). How People Learn, Brain, Mind, Experience, and School. Washington, D.C.: National Academy Press

Research answers to commonly asked questions:

"Can PhET sims replace real lab equipment?"

Our studies have shown that PhET sims are more effective for conceptual understanding; however, there are many goals of hands-on labs that simulations do not address. For example, specific skills relating to the functioning of equipment. Depending on the goals of your laboratory, it may be more effective to use just sims or a combination of sims and real equipment

"Do students learn if I just tell them to go home and play with a sim?"

Most students do not have the necessary drive to spend time playing with a science simulation (they're fun, but not that fun) on their own time unless there is a direct motivation such as their grade. This is one of the reasons we are pursuing the project of how to best integrate sims into homework.

"Where is the best place to use PhET sims in my course?"

We have found PhET sims to be very effective in lecture, in class activities, lab and homework. They are designed with minimal text so that they can easily be integrated into every aspect of a course.

Our immediate interests are:

Use of analogy to construct understanding: Students use analogies in sims to make sense of unfamiliar phenomena. Representations play a key role in student use of analogy.

Simulations as tools for changing classroom norms: Sims are shaped by socio-cultural norms of science, but can also be used to change the traditional norms of how students engage in the classroom.

Specific features of sims that promote learning and engaged exploration: Our design principles identify key characteristics of sims that make them productive tools for student engagement. Now we wish to study in detail how each feature impacts student understanding.

Integrating simulations into homework: Simulations have unique features that are not available in most learning tools (interactivity, animation, dynamic feedback, allow for productive exploration).

Effectiveness of Chemistry simulations: We have just begun investigating the envelope of where and how chemistry simulations can be effective learning tools.

Publications and Presentations

About PhET sims

Student Engagement and Learning with PhET Interactuve Simulations, W. K. Adams, Multimedia in Physics Teaching and Learning Proceedings, 2009.
Making On-Line Science Course Materials Easily Translatable and Accessible WorldWide: Challenges and Solutions, W. K. Adams, H. Alhadlaq, C. V. Malley, K. K. Perkins, J. Olson, F Alshaya, S. Alabdulkareem, C. E. Wieman, Multimedia in Physics Teaching and Learning Proceedings, 2009.
Making On-Line Science Course Materials Easily Translatable and Accessible Worldwide: Technical Concerns, C. V. Malley, J. O. Olson, Multimedia in Physics Teaching and Learning Proceedings, 2009.
PhET: Simulations That Enhance Learning, C.E. Wieman, W.K. Adams, K.K. Perkins, Science, 322/682-683 , October 2008.
Oersted Medal Lecture 2007: Interactive simulations for teaching physics: What works, what doesn't, and why, C.E. Wieman, K.K. Perkins, W.K. Adams, American Journal of Physics, 76, 393 , May 2008.
A Powerful Tool For Teaching Science, C. E. Wieman and K. K. Perkins, Nature Physics, p. 290-292 , May 2006.
PhET: Interactive Simulations for Teaching and Learning Physics, Katherine Perkins, Wendy Adams, Michael Dubson, Noah Finkelstein, Sam Reid, Carl Wieman, Ron LeMaster, The Physics Teacher, 44(1), 18 , 2006.
Transforming Physics Education, C. E. Wieman and K. K. Perkins, Physics Today, November 2005. pdf )
Free On-line Resource Connects Real-life Phenomena to Science, K. K. Perkins and C. E. Wieman, Physics Education, p. 93-95 , January 2005.
The Physics Education Technology Project: A New Suite of Physics Simulations, K. K. Perkins, W. K. Adams, N. Finkelstein, R. LeMaster, S. Reid, M. Dubson, N. Podolefsky, K. Beck and C. Wieman, Poster Presented at AAPT Summer Meeting, 2004.
Should a Fortran-savvy educator learn Java, Flash, both, or neither?, M. Dubson, Talk presented at AAPT Summer Meeting, 2004.

Important features for effective simulation design (predominantly interview data)

What Levels of Guidance Promote Engaged Exploration with Interactive Simulations?, W. K. Adams, A. Paulson and C. E. Wieman, PERC Proceedings, 2009.
How does the type of guidance student use of an interactive simulation?, A. Paulson, K. Perkins, and W. Adams, Phys. Rev.ST Phys. Educ. Res., in review , 2009.
A Study of Educational Simulations Part II - Interface Design, W. K. Adams, S. Reid, R. LeMaster, S. B. McKagan, K. K. Perkins, M. Dubson and C. E. Wieman, Journal of Interactive Learning Research, 19(4), 551-577 , October 2008.
A Study of Educational Simulations Part I - Engagement and Learning, W. K. Adams, S. Reid, R. LeMaster, S. B. McKagan, K. K. Perkins, M. Dubson and C. E. Wieman, Journal of Interactive Learning Research, 19(3), 397-419 , July 2008.
Developing and Researching PhET simulations for Teaching Quantum Mechanics, S. B. McKagan, K. K. Perkins, M. Dubson, C. Malley, S. Reid, R. LeMaster, and C. E. Wieman, American Journal of Physics, 76, 406 , May 2008.
Research-Based Design Features of Web-based Simulations, W. K. Adams, N. D. Finkelstein, S. Reid, M. Dubson, N. Podolefsky, C. E. Wieman, R. LeMaster, Talk presented at AAPT Summer Meeting, 2004.

Research on in-class use

Teaching Physics using PhET Simulations, C. Wieman, W. Adams, P. Loeblein, and K. Perkins, The Physics Teacher, in press , 2010.
A Research-Based Curriculum for Teaching the Photoelectric Effect, S. B. McKagan, W. Handley, K. K. Perkins, and C. E. Wieman, American Journal of Physics, 77, 87 , January 2009.
High-Tech Tools for Teaching Physics: the Physics Education Technology Project, N. D. Finkelstein, W. K. Adams, C. K. Kller, k. K. Perkins, C. E. Wieman and the PhET Team, Journal of Online Teaching and Learning, September 2006.
Assessing the Effectiveness of a Computer Simulation in Introductory Undergraduate Environments, C. J. Keller, N. D. Finkelstein, K. K. Perkins, and S. J. Pollock, PERC Proceedings, 2006.
Assessing the effectiveness of a computer simulation in conjunction with Tutorials in Introductory Physics in undergraduate physics recitations, C. J. Keller, N.D. Finkelstein, K. K. Perkins, and S. J. Pollock, PERC Proceedings, 2005.
When learning about the real world is better done virtually: a study of substituting computer simulations for laboratory equipment, N.D. Finkelstein, W. K. Adams, C. J. Keller, P. B. Kohl, K. K Perkins, N. S. Podolefsky, S. Reid, R. LeMaster, Phys. Rev. ST Phys. Educ. Res. 1, 010103, 2005.
Incorporating Simulations in the Classroom - A survey of Research Results from the Physics Education Technology Project, K. K. Perkins, W. K. Adams, N. D. Finkelstein, M. Dubson, S. Reid, R. LeMaster and C. E. Wieman, Talk presented at AAPT Summer Meeting, 2004.
Can Computer Simulations Replace Real Equipment in Undergraduate Laboratories?, N. D. Finkelstein, K. K. Perkins, W. Adams, P. Kohl, and N. Podolefsky, PERC Proceedings, 2004.

Students Perceptions About Learning

Students know what physicists believe, but they don't agree: A study using the CLASS survey, Kara E. Gray, Wendy K. Adams, Carl E. Wieman, and Katherine K. Perkins, Physical Review Special Topics, November 2008.
A deeper look at student learning of quantum mechanics: the case of tunneling, S. B. McKagan, K. K. Perkins, and C. E. Wieman, Physical Review Special Topics: PER, 4, 020103 , October 2008.
Why we should teach the Bohr model and how to teach it effectively, S. B. McKagan, K. K. Perkins, and C. E. Wieman, Physical Review Special Topics: PER, 4, 010103 , March 2008.
Reforming a large lecture modern physics course for engineering majors using a PER-based design, S. B. McKagan, K. K. Perkins, and C. E. Wieman, Proceedings of the Physics Education Research Conference 2006, 2007.
Exploring Student Understanding of Energy through the Quantum Mechanics Conceptual Survey, S. B. McKagan and C. E. Wieman, PERC Proceedings 2005, 2006.
A new instrument for measuring student beliefs about physics and learning physics: the Colorado Learning Attitudes about Science Survey, W. K. Adams, K. K. Perkins, N. Podolefsky, M. Dubson, N. D. Finkelstein and C. E. Wieman, Phys. Rev. ST Phys. Educ. Res. 2, 010101, 2006.
The surprising impact of seat location on student performance, K. K. Perkins and C. E. Wieman, The Physics Teacher, 43, p. 30-33 , 2005.
Minimize Your Mistakes by Learning from Those of Others, C. E. Wieman, The Physics Teacher, 43, 252-253 , 2005.
Towards characterizing the relationship between students' interest in and their beliefs about physics, K.K. Perkins, M.M. Gratny, W.K. Adams, N.D. Finkelstein and C.E. Wieman, PERC Proceedings, 2005.
The Design and Validation of the Colorado Learning Attitudes about Science Survey, W. K. Adams, K. K. Perkins, M. Dubson, N. D. Finkelstein and C. E. Wieman, PERC Proceedings, 2004.
Correlating Student Beliefs With Student Learning Using The Colorado Learning Attitudes about Science Survey, K. K. Perkins, W. K. Adams, N. D. Finkelstein, S. J. Pollock, and C. E. Wieman, PERC Proceedings, 2004.

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