Top

Journal of Science Education and Technology

Published in:

26-12-2017

Tools for Science Inquiry Learning: Tool Affordances, Experimentation Strategies, and Conceptual Understanding

Authors: Engin Bumbacher, Shima Salehi, Carl Wieman, Paulo Blikstein

Published in: Journal of Science Education and Technology | Issue 3/2018

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Manipulative environments play a fundamental role in inquiry-based science learning, yet how they impact learning is not fully understood. In a series of two studies, we develop the argument that manipulative environments (MEs) influence the kind of inquiry behaviors students engage in, and that this influence realizes through the affordances of MEs, independent of whether they are physical or virtual. In particular, we examine how MEs shape college students’ experimentation strategies and conceptual understanding. In study 1, students engaged in two consecutive inquiry tasks, first on mass and spring systems and then on electric circuits. They either used virtual or physical MEs. We found that the use of experimentation strategies was strongly related to conceptual understanding across tasks, but that students engaged differently in those strategies depending on what ME they used. More students engaged in productive strategies using the virtual ME for electric circuits, and vice versa using the physical ME for mass and spring systems. In study 2, we isolated the affordance of measurement uncertainty by comparing two versions of the same virtual ME for electric circuits—one with and one without noise—and found that the conditions differed in terms of productive experimentation strategies. These findings indicate that measures of inquiry processes may resolve apparent ambiguities and inconsistencies between studies on MEs that are based on learning outcomes alone.

previous article Teaching Journalistic Texts in Science Classes: the Importance of Media Literacy

next article Implementation of a Curriculum-Integrated Computer Game for Introducing Scientific Argumentation

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Available only for authorised users

Alternative explanations are that combinations of ME provide multiple representations, which leads to increased learning benefits, irrespective of affordances. The current state of research cannot exclude these alternative explanations (Lazonder and Ehrenhard 2014).

In Lazonder and Ehrenhard (2014), the researcher ensured that each experiments students designed was unconfounded.

The regression equation was marginally significant, F(4, 29)= 2.2, p = .09, with an adjusted R ²=.13.

M is the mean and SD the standard deviation of the sample

The regression equation was significant, F(3, 61)= 8.4, p<.001, with an adjusted R ²=.26.

The average silhouette score was .37. Nevertheless, the clusters are reasonably coherent in terms of experimentation strategies.

Specifically, we controlled for pre-test scores, medium, their interaction, and the number of circuits built.

The correlations are based on a total of 32 participants, excluding participants from POE and participants with perfect pre-test scores.

We will discuss why POE did not show any effect in the section on limitations of the studies.

Random noise was designed as Gaussian noise centered on the theoretically correct current value, and spanning a maximum range of about 10% of the current value, up to a maximum of about 0.6Amp.

Ainsworth S., VanLabeke N. (2004) Multiple forms of dynamic representation. Learning and Instruction 14(3):241–255CrossRef

Buffler A., Allie S., Lubben F. (2001) The development of first year physics students’ ideas about measurement in terms of point and set paradigms. International Journal of Science Education 23(11):1137–1156CrossRef

Chan J., Pondicherry T., Blikstein P. (2013) LightUp: an augmented, learning platform for electronics. In: Proceedings of the 12th international conference on interaction design and children, IDC ’13. ACM, New York, pp 491–494

Chen S. (2010) The view of scientific inquiry conveyed by simulation-based virtual laboratories. Computers & Education 55(3):1123–1130CrossRef

Chen Z., Klahr D. (1999) All other things being equal: acquisition and transfer of the control of variables strategy. Child development 70(5):1098–1120CrossRef

Chen S., Chang W.-H., Lai C.-H., Tsai C.-Y. (2014) A comparison of students’ approaches to inquiry, conceptual learning, and attitudes in simulation-based and microcomputer-based laboratories. Science Education 98 (5):905–935CrossRef

Chien K.-P., Tsai C.-Y., Chen H.-L., Chang W.-H., Chen S. (2015) Learning differences and eye fixation patterns in virtual and physical science laboratories. Computers & Education 82:191–201CrossRef

Chini J.J., Madsen A., Gire E., Rebello N.S., Puntambekar S. (2012) Exploration of factors that affect the comparative effectiveness of physical and virtual manipulatives in an undergraduate laboratory. Physics Review ST Physics Education Research 8(1):010113CrossRef

Chinn C.A., Malhotra B.A. (2002a) Children’s responses to anomalous scientific data: how is conceptual change impeded? Journal of Educational Psychology 94(2):327–343CrossRef

Chinn C.A., Malhotra B.A. (2002b) Epistemologically authentic inquiry in schools: a theoretical framework for evaluating inquiry tasks. Science Education 86(2):175–218CrossRef

de Jong T., van Joolingen W.R (1998) Scientific discovery learning, with computer simulations of conceptual domains. Review of Educational Research 68(2):179CrossRef

Conlin L. (2014) Supporting middle schoolers’ use of inquiry strategies for discovering multivariate relations. In: Polman J.L., Kyza E.A., O’Neill D.K., Tabak I., Penuel W.R., Jurow A.S., O’Connor K. , Lee T., D’Amico L. (eds) Interactive physics simulations, Boulder

de Jong T., Linn M.C., Zacharia Z.C (2013) Physical and virtual laboratories, in science and engineering education. Science 340(6130):305–308CrossRef

Duschl R.A., Grandy R.E. (2008) Teaching scientific inquiry: recommendations for research and implementation. Sense Publishers

Finkelstein N.D., Adams W.K., Keller C.J., Kohl P.B., Perkins K.K., Podolefsky N.S., Reid S., LeMaster R. (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 1:1

Fischer K.W. (1980) A theory of cognitive development: the control and construction of hierarchies of skills. Psychological Review 87(6):477–531CrossRef

Gire E., Carmichael A., Chini J.J., Rouinfar A., Rebello S., Smith G., Puntambekar S. (2010) The effects of physical and virtual manipulatives on students’ conceptual learning about pulleys. In: Proceedings of the 9th international conference of the learning sciences - volume 1, ICLS ’10. International Society of the Learning Sciences, Chicago, pp 937–943

Gunstone R.F., Mitchell I.J. (2005) Metacognition and conceptual change. In Teaching science for understanding (pp. 133–163). Elsevier

Heradio R., de la Torre L., Galan D., Cabrerizo F.J., Herrera-Viedma E., Dormido S. (2016) Virtual and remote labs in education: a bibliometric analysis. Computers & Education 98:14–38CrossRef

Hofstein A., Lunetta V.N. (2004) The laboratory in science education: foundations for the twenty-first century. Science Education 88(1):28–54CrossRef

Hsu Y.-S., Thomas R.A. (2002) The impacts of a web-aided instructional simulation on science learning. International Journal of Science Education 24(9):955–979CrossRef

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(8):803–821CrossRef

Jaakkola T. (2012) Thinking outside the box: enhancing science teaching by combining (instead of contrasting) laboratory and simulation activities

Jaakkola T., Nurmi S. (2008) Fostering elementary school students’ understanding of simple electricity by combining simulation and laboratory activities. Journal of Computer Assisted Learning 24(4):271–283CrossRef

Kanari Z., Millar R. (2004) Reasoning from data: how students collect and interpret data in science investigations. Journal of Research in Science Teaching 41(7):748–769CrossRef

Kearney M., Treagust D.F., Yeo S., Zadnik M.G. (2001) Student and teacher perceptions of the use of multimedia supported predict–observe-explain tasks to probe understanding. Research in Science Education 31 (4):589–615CrossRef

Klahr D., Dunbar K. (1988) Dual space search during scientific reasoning. Cognitive Science 12(1):1–48CrossRef

Klahr D., Nigam M. (2004) The equivalence of learning paths in early science instruction effects of direct instruction and discovery learning. Psychological Science 15(10):661–667CrossRef

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(1):183–203CrossRef

Kuhn D., Dean D. (2005) Is developing scientific thinking all about learning to control variables? Psychological Science 16(11):866–870CrossRef

Kuhn D., Iordanou K., Pease M., Wirkala C. (2008) Beyond control of variables: what needs to develop to achieve skilled scientific thinking? Cognitive Development 23(4):435–451CrossRef

Lazonder A., Ehrenhard S. (2014) Relative effectiveness of physical and virtual manipulatives for conceptual change in science: how falling objects fall. Journal of Computer Assisted Learning 30(2):110–120CrossRef

Levy S.T., Wilensky U. (2006) Gas laws and beyond: strategies in exploring models of the dynamics of change in the gaseous state. In: Buckley B., Gobert J., Kraicik J. (eds) Supporting science learning and science education reform with information technologies. Paper presented at the National Association for Research in Science Teaching, San Francisco

Levy S.T., Wilensky U. (2011) Mining students’ inquiry actions for understanding of complex systems. Computers & Education 56(3):556–573CrossRef

Marshall J.A., Young E.S. (2006) Preservice teachers’ theory development in physical and simulated environments. Journal of Research in Science Teaching 43(9):907–937CrossRef

McDermott L.C., Shaffer P.S. (1992) Research as a guide for curriculum development: an example from introductory electricity. Part I: investigation of student understanding. American Journal of Physics 60(11):994–1003CrossRef

McElhaney K. (2010) Making controlled experimentation more informative in inquiry investigations

McElhaney K.W., Chang H.-Y., Chiu J.L., Linn M.C. (2015) Evidence for effective uses of dynamic visualisations in science curriculum materials. Studies in Science Education 51(1):49–85CrossRef

Olympiou G., Zacharia Z.C. (2012) Blending physical and virtual manipulatives: an effort to improve students’ conceptual understanding through science laboratory experimentation. Science Education 96(1):21–47CrossRef

Olympiou G., Zacharias Z., de Jong T. (2013) Making the invisible visible: enhancing students’ conceptual understanding by introducing representations of abstract objects in a simulation. Instructional Science 41(3):575–596CrossRef

Parnafes O. (2006) Developing conceptual understanding through the use of computer-based representations. In: The learning man in the technological era, proceedings of the 1 St Chais conference on instructional technology research. Open University Press, Israel

Paulson A., Perkins K.K., Adams W.K. (2009) How does the type of guidance affect student use of an interactive simulation. Physical Review Special Topics-Physics Education Research, In review, 141–158

Pedaste M., Mäeots M., Siiman L.A., de Jong T., van Riesen S.A.N., Kamp E.T., Manoli C.C., Zacharia Z.C., Tsourlidaki E. (2015) Phases of inquiry-based learning: definitions and the inquiry cycle. Educational Research Review 14:47–61CrossRef

Perez S., Massey-Allard J., Butler D., Ives J., Bonn D.A., Yee N., Roll I. (2017) Identifying productive inquiry in an exploratory virtual labs using sequence mining. In: Proceedings of the 18th international conference on artificial intelligence in education. Wuhan

Perkins K., Adams W., Dubson M., Finkelstein N., Reid S., Wieman C., LeMaster R. (2005) PhET: interactive simulations for teaching and learning physics. The Physics Teacher 44(1):18–23CrossRef

Pyatt K., Sims R. (2011) Virtual and physical experimentation in inquiry-based science labs: attitudes, performance and access. Journal of Science Education and Technology 21(1):133–147CrossRef

Quinn H., Schweingruber H., Keller T. (2012) A framework for K-12 science education, practices, crosscutting concepts, and core ideas. National Academies Press

Renken M.D., Nunez N. (2013) Computer simulations and clear observations do not guarantee conceptual understanding. Learning and Instruction 23:10–23CrossRef

Reynolds A.P., Richards G., de la Iglesia B., Rayward-Smith V.J. (2006) Clustering rules: a comparison of partitioning and hierarchical clustering algorithms. Journal of Mathematics Modelling Algorithm 5(4):475–504CrossRef

Rickey D., Stacy A.M. (2000) The role of metacognition in learning chemistry. Journal of Chemical Education 77(7):915CrossRef

Rousseeuw P.J. (1987) Silhouettes: a graphical aid to the interpretation and validation of cluster analysis. Journal of Computational and Applied Mathematics 20:53–65CrossRef

Salehi S., Keil M., Kuo E., Wieman C.E. (2015) How to structure an unstructured activity: generating physics rules from simulation or contrasting cases. In: Churukian A. D., Jones D. L., Ding L. (eds) 2015 physics education research conference, College Park, pp 291–294

Sandoval W.A., Reiser B.J. (2004) Explanation-driven inquiry: integrating conceptual and epistemic scaffolds for scientific inquiry. Science Education 88(3):345–372CrossRef

Schauble L. (1996) The development of scientific reasoning in knowledge-rich contexts. Developmental Psychology 32(1):102CrossRef

Schauble L., Glaser R., Raghavan K., Reiner M. (1992) The integration of knowledge and experimentation strategies in understanding a physical system. Applied Cognitive Psychology 6(4):321–343CrossRef

Siegler R.S., Crowley K. (1991) The microgenetic method. A direct means for studying cognitive development. American Psychologist 46(6):606–620CrossRef

Toth E.E., Morrow B.L., Ludvico L.R. (2009) Designing blended inquiry learning in a laboratory context: a study of incorporating hands-on and virtual laboratories. Innovative Higher Education 33(5):333–344CrossRef

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(2):149–173CrossRef

van der Meij J., de Jong T. (2006) Supporting students’ learning with multiple representations in a dynamic simulation-based learning environment. Learning and Instruction 16(3):199–212CrossRef

Windschitl M. (2000) Supporting the development of science inquiry skills with special classes of software. ETR&D 48(2):81–95CrossRef

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 sea. Journal of Research in Science Teaching 43(1):25–42CrossRef

Worsley M., Blikstein P. (2015) Leveraging multimodal learning analytics to differentiate student learning strategies. In: Proceedings of the fifth international conference on learning analytics and knowledge, LAK ’15. ACM, New York, pp 360–367

Zacharia Z.C. (2007) Comparing and combining real and virtual experimentation: an effort to enhance students’ conceptual understanding of electric circuits. Journal of Computer Assisted Learning 23(2):120–132CrossRef

Zacharia Z.C., de Jong T. (2014) The effects on students’ conceptual understanding of electric circuits of introducing virtual manipulatives within a physical manipulatives-oriented curriculum. Cognition and Instruction 32(2):101–158CrossRef

Zacharia Z.C., Michael M. (2016) Using physical and virtual manipulatives to improve primary school students’ understanding of concepts of electric circuits. In: Riopel M., Smyrnaiou Z. (eds) New developments in science and technology education, number 23 in innovations in science education and technology. Springer International Publishing, pp 125–140

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(3):447–457CrossRef

Zacharia Z.C., Manoli C., Xenofontos N., de Jong T., Pedaste M., van Riesen S.A.N., Kamp E.T., Mäeots M., Siiman L., Tsourlidaki E. (2015) Identifying potential types of guidance for supporting student inquiry when using virtual and remote labs in science: a literature review. Educational Technology Research and Development 63(2):257–302CrossRef

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(9):1021–1035CrossRef

Zimmerman C. (2000) The development of scientific reasoning skills. Developmental Review 20(1):99–149CrossRef

Zimmerman C. (2007) The development of scientific thinking skills in elementary and middle school. Developmental Review 27(2):172–223CrossRef

Title: Tools for Science Inquiry Learning: Tool Affordances, Experimentation Strategies, and Conceptual Understanding
Authors: Engin Bumbacher
Shima Salehi
Carl Wieman
Paulo Blikstein
Publication date: 26-12-2017
Publisher: Springer Netherlands
Published in: Journal of Science Education and Technology / Issue 3/2018
Print ISSN: 1059-0145
Electronic ISSN: 1573-1839
DOI: https://doi.org/10.1007/s10956-017-9719-8

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 3/2018

Modern Scientific Literacy: A Case Study of Multiliteracies and Scientific Practices in a Fifth Grade Classroom

Effectiveness of an Asynchronous Online Module on University Students’ Understanding of the Bohr Model of the Hydrogen Atom

Implementation of a Curriculum-Integrated Computer Game for Introducing Scientific Argumentation

After-School and Informal STEM Projects: the Effect of Participant Self-Selection

Teaching Journalistic Texts in Science Classes: the Importance of Media Literacy

Premium Partners