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11 - Computer Simulations in Science Education

from Part II - Technologies in Cyber Behavior

Published online by Cambridge University Press:  06 December 2024

By
Amanda L. Gonczi ,
Lara K. T. Smetana  and
Randy L. Bell
Edited by
Zheng Yan
Zheng Yan
Affiliation:
University at Albany, State University of New York
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Summary

1 Introduction

2 The Complex Construct of Computer Simulations

3 Why Use Computer Simulations?

 3.1 Practical Considerations

 3.2 Conceptual Understanding

 3.3 Procedural Skill Development

 3.4 Science Skills and Practices

 3.5 Systems and Systems Thinking

4 Cyber Behavior and Student Learning with Computer Simulations

 4.1 Learner Variables

 4.2 Teachers Matter

  4.2.1 Instructional Support

  4.2.2 Inquiry-Based Use

5 Software Design Considerations

6 Teacher Education and Simulation Adoption

7 New Directions: Science Computer Simulations and Cyber Behavior

 7.1 Realism

 7.2 Nature of Science

 7.3 Engineering

 7.4 Computational Thinking

 7.5 Remote Learning

 7.6 Assessment

8 Future Directions for Research

9 Conclusion

Keywords

science educationcomputer simulationscyber behaviorinquiryengineeringsystems thinkingnature of sciencesoftware designtechnology adoption
Type
Chapter
Information
The Cambridge Handbook of Cyber Behavior , pp. 319 - 352
Publisher: Cambridge University Press
Print publication year: 2023

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References

Adams, W. K., Reid, S., Lemaster, R., McKagan, S. B., Perkins, K., Dubson, M., & Wieman, C. E. (2008). A student of educational simulations part II – Interface design. Journal of Interactive Learning Research, 19, 551577.Google Scholar
Aho, A. V. (2011). Ubiquity symposium: Computation and computational thinking. Ubiquity, 2011, 28.Google Scholar
Akpan, J., & Strayer, J. (2010). Which comes first? The use of computer simulation of frog dissection or conventional dissection as academic exercise? Journal of Computers in Mathematics and Science Teaching, 29, 113138.Google Scholar
Allen, M. (2017). The sage encyclopedia of communication research methods (Vols. 1–4). SAGE Publications.CrossRefGoogle Scholar
Aldrich, C. (2009). Learning online with games, simulations and virtual worlds. Jossey-Bass.Google Scholar
Baggott La Velle, L., Mcfarlane, A., John, P. D., & Brawn, R. (2004). According to the promises: The subculture of school science, teachers’ pedagogic identity and the challenge of ICT. Education, Communication & Information, 4(1), 109129.CrossRefGoogle Scholar
Barr, V., & Stephenson, C. (2011). Bringing computational thinking to K-12: What is involved and what is the role of the computer science education community? Acm Inroads2(1), 4854.CrossRefGoogle Scholar
Başer, M. (2006). Effects of conceptual change and traditional confirmatory simulations on pre-service teachers’ understanding of direct current circuits. Journal of Science Education and Technology, 15, 367382.CrossRefGoogle Scholar
Başer, M., & Durmuş, S. (2009). The effectiveness of computer supported versus real laboratory inquiry learning environments on the understanding of direct current electricity among pre-service elementary school teachers. Eurasia Journal of Mathematics, Science & Technology, 6, 4761.Google Scholar
Bell, R. L., & Lederman, N. G. (2003). Understandings of the nature of science and decision making on science and technology-based issues. Science Education, 87, 352377.CrossRefGoogle Scholar
Bell, R. L., Smetana, L., & Binns, I. (2005). Simplifying inquiry instructionThe Science Teacher72(7), 3033.Google Scholar
Bell, R. L., & Trundle, K. C. (2008). The use of a computer simulation to promote scientific conceptions of moon phases. Journal of Research in Science Teaching, 3, 346372.CrossRefGoogle Scholar
Ben-Zvi Assaraf, O., & Orion, N. (2010). Systems thinking skills at the elementary school level. Journal of Research in Science Teaching, 47, 540563.CrossRefGoogle Scholar
Bergan-Roller, H. E., Galt, N. J., Chizinski, C. J., Helikar, T., & Dauer, J. T. (2018). Simulated computational model lesson improves foundational systems thinking skills and conceptual knowledge in biology studentsBioScience68(8), 61262.CrossRefGoogle Scholar
Blake, C., & Scanlon, E. (2007). Reconsidering simulations in science education at a distance: Features of effective use. Journal of Computer Assisted Learning, 23, 491502.CrossRefGoogle Scholar
Boblick, J. M. (1970). The use of computer simulations in the teaching of high school physicsScience Education54(1), 7781.CrossRefGoogle Scholar
Boblick, J. M. (1972). Discovering the conservation of momentum through the use of a computer simulation of a one-dimensional elastic collisionScience Education56(3), 337344.CrossRefGoogle Scholar
Bonde, M., Makransky, G., Wandall, J., Larsen, M. V., Morsing, M., Jarmer, H. O., & Sommer, M. (2014). Improving biotech education through gamified laboratory simulations. Nature Biotechnology, 32(7), 694697.CrossRefGoogle ScholarPubMed
Chen, S. (2010). The view of scientific inquiry conveyed by simulation-based virtual laboratories. Computers & Education, 55, 11231130.CrossRefGoogle Scholar
Chiu, J., Gonczi, A., Fu, X., & Burghardt, M. D. (2017). Supporting informed engineering design across formal and informal contexts with WISEngineeringInternational Journal of Engineering Education33(1), 371381.Google Scholar
Chiu, J. L., & Linn, M. C. (2014). Supporting knowledge integration in chemistry with a visualization-enhanced inquiry unitJournal of Science Education and Technology23(1), 3758.CrossRefGoogle Scholar
Clark, D., Nelson, B., Sengupta, P., & D’Angelo, C. (2009, October). Rethinking science learning through digital games and simulations: Genres, examples, and evidence. National Academy of Sciences.Google Scholar
Cuny, J., Snyder, L., Wing, J. M., 2010. Demystifying computational thinking for non-computer scientists. Unpublished manuscript, referenced in www.cs.cmu.edu/~CompThink/resources/TheLinkWing.pdf.Google Scholar
de Jong, T., & van Joolingen, W. R. (1998). Scientific discovery learning with computer simulations of conceptual domains. Review of Educational Research, 68, 179201.CrossRefGoogle Scholar
de Jong, T., Weinberger, A., Girault, I., Kluge, A., Lazonder, A. W., Pedaste, M., Ludvigsen, S., Ney, M., Wasson, B., Wichmann, A., & Geraedts, C. (2012). Using scenarios to design complex technology-enhanced learning environmentsEducational Technology Research and Development60(5), 883901.CrossRefGoogle Scholar
Dohn, N. B. (2011). Situational interest of high school students who visit an aquarium. Science Education, 95, 337357.CrossRefGoogle Scholar
Evagorou, M., Korfiatis, K., Nicolaou, C., & Constantinou, C. (2009). An investigation of the potential of interactive simulations for developing system thinking skills in elementary school: A case study with fifth-graders and sixth-graders. International Journal of Science Education, 31, 655674.CrossRefGoogle Scholar
Faryniarz, J. V., & Lockwood, L. G. (1992). Effectiveness of microcomputer simulations in stimulating environmental problem solving by community college students. Journal of Research in Science Teaching, 29, 453470.CrossRefGoogle Scholar
Finkelstein, N. D., Adams, W. K., Keller, C. J., Kohl, P. B. Perkins, K. K., Podolefsky, N. S., & Reid, S. (2005). When learning about the real world is better done virtually: A study of substituting computer simulations for laboratory equipment. Physical Review Special Topics – Physics Education Research, 1(010103), 18.CrossRefGoogle Scholar
Gerard, L. F., Varma, K., Corliss, S. B., Linn, M. C. (2011). Professional development for technology-enhanced inquiry science. Review of Educational Research, 81, 408448.CrossRefGoogle Scholar
Gonczi, A. L., Chiu, J. L., Maeng, J. L., & Bell, R. L. (2016). Instructional support and implementation structure during elementary teachers’ science education simulation useInternational Journal of Science Education38(11), 18001824.CrossRefGoogle Scholar
Gonczi, A. L., & Chiu, J. L. (2016, July). WISEngineering hydroponics: A technology-enhanced life science engineering design unit. Science Scope 39(9), 1925.CrossRefGoogle Scholar
Gonczi, A. L., Maeng, J. L., & Bell, R. L. (2017). Elementary teachers’ simulation adoption and inquiry-based use following professional development. Journal of Technology and Teacher Education, 25(2), 534.Google Scholar
Gorski, P. (2005Education equity and the digital divide. Association for the Advancement of Computing in Education Journal, 13(1), 345.Google Scholar
Gredler, M. (2004). Games and simulations and their relationships to learning. In Jonassen, D. (Ed.), Handbook of research on educational communications and technology (pp. 571581). Erlbaum.Google Scholar
Hampton, K. (2017). Studying the digital: Directions and challenges for digital methodsAnnual Review of Sociology43(1), 167188.CrossRefGoogle Scholar
Honey, M. A., & Hilton, M. L. (2011). Learning science through computer gamesNational Academies Press.Google Scholar
Huppert, J., Lomask, S. M., & Lazarowitz, R. (2002). Computer simulations in the high school: Students’ cognitive stages, science process skills and academic achievement in microbiology. International Journal of Science Education, 24, 803821.CrossRefGoogle Scholar
Jacobson, M. J., & Wilensky, U. (2006). Complex systems in education: Scientific and educational importance and implications for the learning sciences. The Journal of the Learning Sciences, 15(1), 1134.CrossRefGoogle Scholar
Khan, S. (2011). New pedagogies on teaching science with computer simulations. Journal of Science Education and Technology, 20(3), 215232.CrossRefGoogle Scholar
Kinzie, M., Strauss, R., & Foss., J. (1993). The effects of an interactive dissection simulation on the performance and achievement of high school biology students. Journal of Research in Science Teaching, 30, 9891000.CrossRefGoogle Scholar
Klahr, D., Triona, L. M., & Williams, C. (2007). Hands on what? The relative effectiveness of physical versus virtual materials in an engineering design project by middle school children. Journal of Research in Science Teaching, 44, 183203.CrossRefGoogle Scholar
Koehler, M. J., & Mishra, P. (2009). What is technological pedagogical content knowledge? Contemporary Issues in Technology and Teacher Education, 9(1), 6070.Google Scholar
Kubieck, J. (2005). Inquiry-based learning, the nature of science, and computer technology: New possibilities in science educationCanadian Journal of Learning and Technology31(1), 1–12.CrossRefGoogle Scholar
Lehtinen, A., & Viiri, J. (2017). Guidance provided by teacher and simulation for inquiry-based learning: A case studyJournal of Science Education and Technology26(2), 193206.CrossRefGoogle Scholar
Liao, Y., & Chen, Y (2007). The effect of computer simulation instruction on student learning: A meta-analysis of studies in Taiwan. Journal of Information Technology and Application, 2, 6679.Google Scholar
Lindgren, R., Tscholl, M., Wang, S., & Johnson, E. (2016). Enhancing learning and engagement through embodied interaction within a mixed reality simulationComputers & Education95, 174187.CrossRefGoogle Scholar
López, V., & Pintó, R. (2017). Identifying secondary-school students’ difficulties when reading visual representations displayed in physics simulations. International Journal of Science Education, 39(10), 13531380.CrossRefGoogle Scholar
Mäeots, M., Pedaste, M., & Sarapuu, T. (2008, July). Transforming students’ inquiry skills with computer-based simulations. In 2008 Eighth IEEE International Conference on Advanced Learning Technologies (pp. 938942). IEEE.CrossRefGoogle Scholar
Makransky, G., Thisgaard, M. W., & Gadegaard, H. (2016). Virtual simulations as preparation for lab exercise: Assessing learning of key laboratory skills in microbiology and improvement of essential non-cognitive skills. PLoS ONE, 11(6), e0155895.CrossRefGoogle ScholarPubMed
Maeng, J. L., & Gonczi, A. L. (2020, January). Novice elementary and secondary teachers’ technology and engineering-enhanced science instruction [Paper presentation]. Annual ASTE Conference, San Antonio, Texas.Google Scholar
McElhaney, K. W., Chang, H. Y., Chiu, J. L., & Linn, M. C. (2015). Evidence for effective uses of dynamic visualisations in science curriculum materialsStudies in Science Education51(1), 4985.CrossRefGoogle Scholar
Meir, E., Perry, J., Stal, D., Maruca, S., & Klopfer, E. (2005). How effective are simulated molecular-level experiments for teaching diffusion and osmosis? Cell Biology Education4(3), 235248.CrossRefGoogle ScholarPubMed
National Research Council (NRC). 2012. A framework for K–12 science education: Practices, crosscutting concepts, and core ideas. National Academies Press.Google Scholar
NGSS Lead States. (2013). Next generation science standards: For sates, by sates. The National Academies Press.Google Scholar
Park, M. (2019). Effects of simulation-based formative assessments on students’ conceptions in physicsEURASIA Journal of Mathematics, Science and Technology Education15(7), em1722.CrossRefGoogle Scholar
Plass, J. L., & Schwartz, R. N. (2014). Multimedia learning with simulations and micro-worlds. In Mayer, R. E. (Ed.), Cambridge handbook of multimedia learning (2nd ed., pp. 729761). Cambridge University Press.CrossRefGoogle Scholar
Pope, D. S., Rounds, C. M., & Clarke-Midura, J. (2017). Testing the effectiveness of two natural selection simulations in the context of a large-enrollment undergraduate laboratory classEvolution: Education and Outreach10(1), 3.Google Scholar
Quellmalz, E. S., Timms, M. J., Silberglitt, M., & Buckley, B. C. (2012). Science assessment for all: Integrating science simulations into balanced state science assessment systems. Journal of Research in Science Teaching, 49, 363393.CrossRefGoogle Scholar
Ronen, M., & Eliahu, M. (2000). Simulation – A bridge between theory and reality: The case of electric circuits. Journal of Computer Assisted Learning, 16, 1426.CrossRefGoogle Scholar
Rutten, N., van Joolingen, W. R., & van der Veen, J. T. (2012). The learning effects of computer simulations in science education. Computers & Education, 58, 136153.CrossRefGoogle Scholar
Saab, N., van Joolingen, W. R., & van Hout-Wolters, H. A. M. (2005). Communication in collaborative discovery learning. British Journal of Educational Psychology, 75, 603621.CrossRefGoogle ScholarPubMed
Scalise, K., Timms, M., Moorjani, A., Clark, L., Holtermann, K., & Irvin, P. (2011). Student learning in science simulations: Design features that promote learning gains. Journal of Research in Science Teaching, 48(9), 10501078.CrossRefGoogle Scholar
Shulman, L. S. (1987). Knowledge and teaching: Foundations of the new reform. Harvard Educational Review, 57, 122.CrossRefGoogle Scholar
Smetana, L., & Bell, R. L. (2012). Computer simulations to support science instruction and learning: A critical review of the literature. International Journal of Science Education, 34(9), 13371370.CrossRefGoogle Scholar
Smetana, L. K., & Bell, R. L. (2014). Which setting to choose: Comparison of whole-class vs. small-group computer simulation use. Journal of Science Education and Technology, 23, 481495.CrossRefGoogle Scholar
Stohlman, S., Moore, T. J., McClelland, J., & Roehrig, G. H. (2011). Impressions of a middle grades STEM integration program. Middle School Journal, 9(1), 3240.CrossRefGoogle Scholar
Tannenbaum, R. S. (2001). Learner interactivity and production complexity in computer based instructional materials. Retrieved September 1, 2020 from http://ubiquity.acm.org/article.cfm?id=367871.Google Scholar
Thisgaard, M. W., & Magransky, G. (2017). Virtual Learning simulations in high school: Effects on cognitive and non-cognitive outcomes and implications on the development of STEM academic and career choice. Frontiers in Psychology, 8(805), 113.CrossRefGoogle ScholarPubMed
Triona, L. M., & Klahr, D. (2003). Point and click or grab and heft: Comparing the influence of physical and virtual instructional materials on elementary school students’ ability to design experiments. Cognition and Instruction, 21, 149173.CrossRefGoogle Scholar
Trundle, K., Bell, R. (2010). The use of a computer simulation to promote conceptual change: A quasi-experimental study. Computers & Education, 54, 10781088.CrossRefGoogle Scholar
Uribe, M., & Magana, A. (2016). Computational simulations as virtual laboratories for online engineering education: A case study in the field of thermoelectricity. Computer Applications in Engineering Education, 24(3), 428442.CrossRefGoogle Scholar
Wang, H., Duh, H., Li, N., Lin, T, & Tsai, C. (2014). An investigation of university students’ collaborative inquiry learning behaviors in an augmented reality simulation and a traditional simulation. Journal of Science Education and Technology, 23, 682692.CrossRefGoogle Scholar
Wecker, C. Kohnle, C., & Fischer, F. (2007). Computer literacy and inquiry learning: When geeks learn less. Journal of Computer Assisted Learning, 23, 133144.CrossRefGoogle Scholar
Windschitl, M. (2000). Supporting the development of science inquiry skills with special classes of software. Educational Technology Research and Development, 48, 8195.CrossRefGoogle Scholar
Windschitl, M., & Andre, T. (1998). Using computer simulations to enhance conceptual change: The roles of constructivist instruction and student epistemological beliefs. Journal of Research in Science Teaching, 35, 145160.3.0.CO;2-S>CrossRefGoogle Scholar
Winn, W., Stahr, F., Sarason, C., Fruland, R., Oppenheimer, P., & Lee, Y. L. (2006). Learning oceanography from a computer simulation compared with direct experience at seaJournal of Research in Science Teaching43(1), 2542.CrossRefGoogle Scholar
Yan, Z. (2013). The science of cyber behavior: An emerged field of researchInternational Journal of Cyber Behavior, Psychology and Learning3(2), 82–87.CrossRefGoogle Scholar
Yaşar, O. (2016). Cognitive aspects of computational modeling and simulation in teaching and learning. Journal of Computational Science Education, 7(1), 214.CrossRefGoogle Scholar
Zacharia, Z. C., Loizou, E., & Papaevripidou, M. (2012). Is physicality an important aspect of learning through science experimentation among kindergarten students? Early Childhood Research Quarterly, 27, 447457.CrossRefGoogle Scholar
Zacharia, Z. C., Olympiou, G., & Papaevripidou, M. (2008). Effects of experimenting with physical and virtual manipulatives on students conceptual understanding in heat and temperature. Journal of Research in Science Teaching, 45, 10211035.CrossRefGoogle Scholar

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