PhET Interactive Simulations

PhET Interactive Simulations

Screenshot of PhET's Circuit Construction Kit Simulation
Type of site
Online education
Available in English, Afrikaans, Arabic, Brazilian Portuguese, Chinese, Danish, Dutch, Finnish, French, German, Greek, Hebrew, Indonesian, Italian, Japanese, Korean, Norwegian, Persian, Polish, Russian, Spanish, Thai, Turkish, Vietnamese
Created by Carl Wieman
Slogan(s) "To advance science and math literacy and education worldwide through free interactive simulations"
Website phet.colorado.edu
Commercial No
Launched 2002
Content license
Creative Commons (CC-BY)

PhET Interactive Simulations, a project at the University of Colorado Boulder, is a non-profit[1] open educational resource (OER) project founded in 2002 by Nobel Laureate Carl Wieman. PhET began with Wieman’s vision to improve the way science is taught and learned. Their stated mission is "To advance science and math literacy and education worldwide through free interactive simulations."

The project acronym "PhET" originally stood for "Physics Education Technology," but PhET soon expanded to other disciplines. The project now designs, develops, and releases over 125 free interactive simulations for educational use in the fields of physics, chemistry, biology, earth science, and mathematics. The simulations have been translated into over 65 different languages, including Spanish, Chinese, German, and Arabic; and in 2011, the PhET website received over 25 million visitors.[2]

In October 2011, PhET Interactive Simulations was chosen as the 2011 Microsoft Education Tech Award laureate.[3] The Tech Awards, presented by The Tech Museum of Innovation, honor innovators from around the world for technology benefitting humanity.[4]

History

In 2001, Wieman won the Nobel Prize in Physics, along with Eric Cornell and Wolfgang Ketterle for fundamental studies of the Bose-Einstein condensate.[5] After winning his Nobel prize, Wieman became particularly involved with efforts at improving science education and has conducted educational research on science instruction. He helped write Physics 2000[6] to provide simulations to explain his work in creating the Bose-Einstein Condensate. As he gave public lectures, some incorporating simulations,[7] he noticed that "often the simulations would be the primary thing people would remember from my talk. Based on their questions and comments, it appeared that they consistently learned the physics represented in the simulations."[8] He then used money from a grant from the National Science Foundation Distinguished Teaching Scholars program, the Kavli Foundation, and a portion of his Nobel Prize money to found PhET to improve the way that physics is taught and learned. The PhET simulations differ from the Physics 2000 ones because users can interact with the simulation to change conditions whereas the Physics 2000 simulations are just videos.[9]

In 2007, Wieman moved to Vancouver, British Columbia while retaining 20% faculty position at the University of Colorado Boulder. The current director of PhET is Dr. Katherine Perkins. Perkins received her B.A. in 1992 and Ph.D. in 2000 from Harvard University.[10] She has been with PhET since January 2003. Perkins hopes that the simulations’ accessibility and interactive nature will increase scientific literacy and promote student engagement in the classroom. [11]

Organization

PhET Interactive Simulations is part of the University of Colorado Boulder which is a member of the Association of American Universities.[12] The team changes over time and has about 16 members consisting of professors, post-doctoral students, researchers, education specialists, software engineers (sometimes contractors), educators, and administrative assistants.[13] The current director of PhET is Dr. Katherine Perkins.

Design and educational impact

PhET Interactive Simulations incorporates research-based practices on effective teaching to enhance the learning of science and mathematics concepts.[14] The simulations are designed to be flexible so that they can be used as lecture demonstrations, labs, or homework activities.[15] They use an intuitive, game-like environment where students can learn through scientist-like exploration within a simplified environment, where dynamic visual representations make the invisible visible, and where science ideas are connected to real-world phenomena.

A PhET simulation starts with three to five people including a content expert (scientist), a teacher, an educational researcher, and a professional software developer. The design begins with identifying specific learning goals that have proven to be conceptually difficult based on teachers' experiences in the classroom. The simulation design, look and feel is storyboarded, discussed, and then finally "coded." Each simulation is user tested through interviews with students and in classrooms, re-worked as needed and re-tested, before released on the PhET website.[16]

Along with testing every simulation, the PhET team performs education research on their simulations. They have shown in their research that when students explore simulations in addition to traditional labs, student concept understanding improves.[17]

PhET usage by educators

While PhET Interactive Simulations develops the simulations, it is primarily teachers and publishers who develop the educational activities which use the simulations, sharing these with the community. Contributors on the PhET site follow Open Education Practices (OEP), enabling teachers to use or adapt the activities freely.[18]

PhET sim used part of a large lecture course
High School Students using PhET for a lab

Other Open Education Resource organizations that provide ideas and reviews include:


Professional organizations also provide ideas for using PhET simulations. In the JCE Chemical Education Xchange (ChemEd X), members have blogged about how using PhET can help with specific topics like Stoichiometry Resources,[36] First Week Excitement,[37] PHYSICS 2000,[38] and Adding Inquiry to Atomic Theory.[39]

Research on use of simulations in education

The National Science Foundation has provided grants for several organizations to study PhET use:[40]

Other research grants:

References

  1. Support PhET
  2. Guttenplan, D.D. (December 11, 2011). "Web Tutors Become Stars Far from Classroom". New York Times.
  3. "The Tech Award 2011".
  4. McCracken, Harry (October 21, 2011). "Meet the Winners of This Year's Tech Humanitarian Awards". Time.
  5. http://nobelprize.org/nobel_prizes/physics/laureates/2001/public.html
  6. "Physics 2000". University of Colorado Boulder. Retrieved 22 August 2013.
  7. Cornell, E.A.; C.E. Wieman (2002). "Nobel Lectures in Physics 2001". Rev. Mod. Phys. 74 (3): 875–893. doi:10.1103/revmodphys.74.875.
  8. Wieman, Carl; Katherine K. Perkins; Wendy K. Adams (April 2008). "Oersted Medal Lecture 2007: Interactive simulations for teaching physics: What works, what doesn't, and why". American Journal of Physics. 76 (4): 393. doi:10.1119/1.2815365.
  9. "Reviews Web Watch- Interactive Simulations" (PDF). 2005 Phys. Educ. 40 81. IOP Publishing. Retrieved 22 August 2013.
  10. Xue, Katherine (May–June 2013). "Science Simulator". Harvard Magazine.
  11. Xue, Katherine (July–August 2012). "Alumni Science Simulator". Harvard Magazine. Retrieved 22 August 2013.
  12. "Association of American Universities".
  13. "About PhET".
  14. Bryan, Joel (June 2006). "Technology for Physics Instruction". Contemporary Issues in Technology and Teacher Education. 6 (2): 230.
  15. Ash, Katie. "Programming Digital Fun Into Science Education". Education Week Digital Directions.
  16. Maki, Peggy (2004). Assessing for Learning: Building a Sustainable Commitment Across the Institution. Sterling, VA: Stylus Publishing. ISBN 1579224407.
  17. Wieman, Carl; Wendy, K. Adams, Katherine K. Perkins (October 2008). "PhET Research: Simulations that Enhance Learning". Science. 322: 682. doi:10.1126/science.1161948. Cite uses deprecated parameter |coauthors= (help)
  18. "PhET For Teachers". PhET Interactive Simulations. Retrieved 23 June 2013.
  19. "National Digital Science Literacy Maps". Retrieved 16 June 2013.
  20. Dushay, Naomi (2003). Analyzing metadata for effective use and re-use. Proceedings of the International Conference on Dublin Core and Metadata Applications.
  21. Developing a Digital National Library for Undergraduate Science, Mathematics, Engineering and Technology Education: Report of a Workshop. Washington, DC: The National Academies Press. 1998. pp. 53–57. ISBN 978-0-309-05977-0.
  22. Kyrillidou, Martha (2005). Developing the DigiQUAL protocol for digital library evaluation. In Proceedings of the 5th ACM/IEEE-CS Joint Conference on Digital Libraries: ACM Press. pp. 172–173.
  23. "MERLOT Physics". MERLOT at California State University. Retrieved 21 June 2013.
  24. Advances in Web-Based Learning - ICWL 2004: Third International Conference, Beijing, China, August 8–11, 2004, Proceedings, Volume 3 (Google eBook)
  25. "MERLOT Physics Showcase". MERLOT at California State University. Retrieved 16 June 2013.
  26. "MERLOT Physics". MERLOT at California State University. Retrieved 16 June 2013.
  27. "Physics Front". AAPT and NSF-NSDL. Retrieved 21 June 2013.
  28. "The Physics Front". AAPT and NSF-NSDL. Retrieved 16 June 2013.
  29. "Physics Front". search for phet activities. AAPT and NSF-NSDL. Retrieved 16 June 2013.
  30. "Pedagogy in Action". Science Education Resource Center @ Carlton College. Retrieved 21 June 2013.
  31. "Pedagogy in Action Library". Science Education Resource Center @ Carlton College. Retrieved 16 June 2013.
  32. "Resources for Using PhET in class". Science Educatio Resource Center @ Carlton College. Retrieved 16 June 2013.
  33. "The International Association for K-12 Online Learning". Retrieved 23 June 2013.
  34. Vander Ark, Tom (June 17, 2013). "10 Ways Smart Cities Develop & Support Teachers". Education Week. Retrieved 23 June 2013.
  35. "Open Educational Resources and Collaborative Content Development – A Practical Guide for State and School Leaders" (PDF). iNACOL. Retrieved 23 June 2013.
  36. Cullen, Deanna. "Stoichiometric Resources". Division of Chemical Education. Retrieved 16 June 2013.
  37. Cullen, Deanna. "First Week Excitement". Division of Chemical Education. Retrieved 16 June 2013.
  38. Cullen, Deanna. "PHYSICS 2000". Division of Chemical Education. Retrieved 16 June 2013.
  39. Cullen, Deanna. "Adding Inquiry to Atomic Theory". Division of Chemical Education. Retrieved 16 June 2013.
  40. "awards". search PhET. National Science Foundation. Retrieved 22 August 2013.
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