Abstract
The study we have carried out aims to characterize 15- to 16-year-old students’ learning progressions throughout the implementation of a teaching–learning sequence on the acoustic properties of materials. Our purpose is to better understand students’ modeling processes about this topic and to identify how the instructional design and actual enactment influences students’ learning progressions. This article presents the design principles which elicit the structure and types of modeling and inquiry activities designed to promote students’ development of three conceptual models. Some of these activities are enhanced by the use of ICT such as sound level meters connected to data capture systems, which facilitate the measurement of the intensity level of sound emitted by a sound source and transmitted through different materials. Framing this study within the design-based research paradigm, it consists of the experimentation of the designed teaching sequence with two groups of students (n = 29) in their science classes. The analysis of students’ written productions together with classroom observations of the implementation of the teaching sequence allowed characterizing students’ development of the conceptual models. Moreover, we could evidence the influence of different modeling and inquiry activities on students’ development of the conceptual models, identifying those that have a major impact on students’ modeling processes. Having evidenced different levels of development of each conceptual model, our results have been interpreted in terms of the attributes of each conceptual model, the distance between students’ preliminary mental models and the intended conceptual models, and the instructional design and enactment.
This is a preview of subscription content, access via your institution.
Notes
Some of the former work on learning pathways has been recently restructured and expanded to the notion of learning progressions. Learning progressions have been referred to by many terms, including conceptual/learning trajectories, conceptual progressions, or profile strands.
References
Acher A, Arcà M, Sanmartí N (2007) Modeling as a teaching learning process for understanding materials: a case study in primary education. Sci Educ 91:398–418
Anderson RD (2002) Reforming science teaching: what research says about inquiry. J Sci Teach Educ 13(1):1–12
Buckley B (2000) Interactive multimedia and model-based learning in biology. Int J Sci Educ 22(9):895–935
Bunge M (1973) Method, model and matter. In: D. Reidel Publishing Company, Dordrecht, Holland
Buty C, Tiberghien A, Le Maréchal JF (2004) Learning hypotheses and an associated tool to design and to analyse teaching-learning sequence. Int J Sci Educ 26(5):579–604
Campbell T, Zhang D, Neilson D (2011) Model based inquiry in the high school physics classroom: an exploratory study of implementation and outcomes. J Sci Educ Technol 20(3):258–269
Chinn C, Malhotra B (2002) Epistemologically authentic inquiry in schools: a theoretical framework for evaluating inquiry tasks. Sci Educ 86:175–218
Clement J (2000) Model based learning as a key research area for science education. Int J Sci Educ 22(9):1041–1053
Corcoran T, Mosher FA, Rogat A (2009) Learning progressions in science: An evidence-based approach to reform. Consortium for Policy Research in Education Report #RR-63. Consortium for Policy Research in Education, Philadelphia, PA
Couso D (in press) Participatory approaches on curriculum design. In: Psillos D, Kariotoglou P (eds) Iterative design of teaching-learning sequences: introducing the science of materials in European schools. Springer Editorial
Design-Based Research Collective (2003) Design-based research: an emerging paradigm for educational inquiry. Educ Res 32(1):5–8
Driver R, Leach J, Scott P, Wood-Robinson C (1994) Young people’s understanding of science concepts: implications of cross-age studies for curriculum planning. Stud Sci Educ 24:75–100
Duit R, Gropengießer H, Kattmann U (2005) Towards science education research that is relevant for improving practice: the model of educational reconstruction. In: Fischer HE (ed) Developing standards in research on science education. Taylor and Francis, London, pp 1–9
Duschl R, Maeng S, Sezen A (2011) Learning progressions and teaching sequences: a review and analysis. Stud Sci Educ 47(2):123–182
Giere RN (1999) Using models to represent reality. In: Magnani L, Nersessian NJ, Thagard P (eds) Model-based reasoning in scientific discovery. Kluwer Academic/Plenum Press, New York, pp 41–57
Gilbert J, Boulter C (1998) Learning science through models and modelling. In: Fraser BJ, Tobin KG (eds) International handbook of science education, Part 1. Kluwer Academic Publishers, Dordretch, Netherlands, pp 53–66
Gobert J, Buckley B (2000) Introduction to model-based teaching and learning in science education. Int J Sci Educ 22(9):891–894
Greca IM, Moreira MA (2000) Mental models, conceptual models, and modelling. Int J Sci Educ 22(1):1–11
Harrison AG, Treagust DF (2002) The particulate nature of matter: challenges in understanding the submicroscopic world. In: Gilbert JK, de Jong O, Justi R, Treagust DF, van Driel JH (eds) Chemical education: towards research-based practice. Kluwer Academic, The Netherlands, pp 189–212
Hernández MI, Couso D, Pintó R (2011) Teaching acoustic properties of materials in secondary school: testing sound insulators. Phys Educ 46(5):559–569
Hernández MI, Couso D, Pintó R (2012) The analysis of students’ conceptions as a support for the design of a teaching/learning sequence on acoustic properties of materials. J Sci Educ Technol 21(6):702–712
Hernández MI, Pintó R (in press) The process of iterative development of a teaching/learning sequence on acoustic properties of materials. In: Psillos D, Kariotoglou P (eds) Iterative design of teaching-learning sequences: introducing the science of materials in European schools. Springer Editorial
Hrepic Z, Zollman D, Rebello S (2010) Identifying students’ mental models of sound propagation: the role of conceptual blending in understanding conceptual change. Phys Rev Spec Top Phys Educ Res 6:1–18
Izquierdo-Aymerich M, Adúriz-Bravo A (2003) Epistemological foundations of school science. Sci Educ 12(1):27–43
Justi R, Gilbert J (2002) Modelling, teachers’ views on the nature of modelling, and implications for the education of modellers. Int J Sci Edu 24(4):369–387
Khan S (2007) Model-based inquiries in chemistry. Sci Educ 91:877–905
Koponen IT (2007) Models and modelling in physics education: a critical re-analysis of philosophical underpinnings and suggestions for revisions. Sci Educ 16:751–773
Leach J, Scott P (2002) Designing and evaluating science teaching sequences: an approach drawing upon the concept of learning demand and a social constructivist perspective on learning. Stud Sci Educ 38:115–142
Lehrer R, Schauble L, Lucas D (2008) Supporting development of the epistemology of inquiry. Cogn Dev 23:512–529
Linder CJ (1993) University physics students’ conceptualizations of factors affecting the speed of sound propagation. Int J Sci Educ 15(6):655–662
Löhner S, van Joolingen WR, Savelsbergh ER, van Hout-Wolters B (2005) Students’ reasoning during modeling in an inquiry learning environment. Comput Hum Behav 21:441–461
Louca LT, Zacharia ZC, Constantinou CP (2011) In quest of productive modeling-based learning discourse in elementary school science. J Res Sci Teach 48(8):919–951
Maurines L (1993) Spontaneous reasoning on the propagation of sound. In: Novak J (ed) Proceedings of the third international seminar on misconceptions and educational strategies in science and mathematics. Cornell University, Ithaca
Méheut M, Psillos D (2004) Teaching-learning sequences: aims and tools for science education research. Int J Sci Educ 26(5):515–535
Mellar H, Bliss J (1994) Introduction: modelling and education. In: Mellar H, Bliss J, Boohan R, Ogborn J, Thompsett C (eds) Learning with artificial worlds: computer based modelling in the curriculum. The Falmer, London, pp 1–7
Millar R (2005) Teaching about energy. Department of Educational Studies, Research Paper, 11. The University of York, York
Minner D, Levy AJ, Century J (2010) Inquiry-based science instruction: what is it and does it matter? Results from a research synthesis years 1984 to 2002. J Res Sci Teach 47(4):474–496
Nersessian NJ (1995) Should physicists preach what they practice? Constructive modeling in doing and learning physics. Sci Educ 4(3):203–226
Nersessian NJ (1999) Model-based reasoning in conceptual change. In: Magnani L, Nersessian NJ, Thagard P (eds) Model-based reasoning in scientific discovery. Kluwer Academic/Plenum Press, New York, pp 5–22
Niedderer H, Goldberg E (1995) Learning pathway and knowledge construction in electric circuits. Paper presented at the First European Conference on Research in Science Education. Leeds, UK
Norman D (1983) Some observations on mental models. In: Gentner D, Stevens A (eds) Mental models. Lawrence Erlbaum Associates, New Jersey
Oh PS, Oh SJ (2011) What teachers of science need to know about models: an overview. Int J Sci Educ 33(8):1109–1130
Pintó R (2005) Introducing curriculum innovations in science: identifying teachers’ transformations and the design of related teacher education. Sci Educ 89(1):1–12
Pintó R, Couso D, Hernández MI, Armengol M, Cortijo C, Martos R, Padilla M, Rios C, Simón M, Sunyer C, Tortosa M (2010) Acoustic properties of materials: teachers’ manual and teaching and learning activities. Nicosia, Cyprus
Rea-Ramirez MA, Clement J, Núñez-Oviedo MC (2008) An instructional model derived from model construction and criticism theory. In: Clement J, Rea-Ramirez MA (eds) Model based learning and instruction in science. Springer, Dordrecht, pp 23–43
Ruthven K, Laborde C, Leach J, Tiberghien A (2009) Design tools in didactical research: instrumenting the epistemological and cognitive aspects of the design of teaching sequences. Educ Res 38(5):329–342
Schwarz CV, Gwekwerere YN (2007) Using a guided inquiry and modeling instructional framework (EIMA) to support preservice K-8 science teaching. Sci Educ 91:158–186
Schwarz CV, Reiser BJ, Davis EA, Kenyon L, Acher A, Fortus D, Shwartz Y, Hug B, Krajcik J (2009) Developing a learning progression for scientific modeling: making scientific modeling accessible and meaningful for learners. J Res Sci Teach 46(6):632–654
Scott PH (1992) Conceptual pathways in learning science: a case study of the development of one student’s ideas relating to the structure of matter. In: Duit R, Goldberg F, Niedderer H (eds) Research in physics learning: theoretical issues and empirical studies. IPN, Kiel, pp 203–224
Stewart J, Cartier JL, Passmore CM (2005) Developing understanding through model-based inquiry. In: Donovan MS, Bransford JD (eds) How students learn. National Research Council, Washington DC, pp 515–565
Talanquer V (2009) On cognitive constraints and learning progressions: the case of “structure of matter”. Int J Sci Educ 31(15):2123–2136
Tiberghien A (1994) Modeling as a basis for analyzing teaching–learning situations. Learn Instr 4:71–87
Tiberghien A, Vince J, Gaidioz P (2009) Design-based research: case of a teaching sequence on mechanics. Int J Sci Educ 31(17):2275–2314
Viennot L (2010) Physics education research and inquiry-based teaching: a question of didactical consistency. In: Kortland K, Klaassen K (eds) Designing theory-based teaching–learning sequences for science education; Proceedings of the symposium in honour of Piet Lijnse at the time of his retirement as professor of physics didactics at Utrecht University. CDBeta Press, Utrecht, pp 37–54
Viennot L, Rainson S (1999) Design and evaluation of a research-based teaching sequence: the superposition of electric field. Int J Sci Educ 21(1):1–16
Viennot L, Chauvet F, Colin P, Rebmann G (2005) Designing strategies and tools for teacher training: the role of critical details, examples in optics. Sci Educ 89:13–27
Wells M, Hestenes D, Swackhamer G (1995) A modeling method for high school physics instruction. Am J Phys 63(7):606–619
Windschitl M, Thompson J, Braaten M (2008) Beyond the scientific method: model-based inquiry as a new paradigm of preference for school science investigations. Sci Educ 92:941–967
Acknowledgments
This study would not have been possible without the sponsorship of the European Communities Research Directorate General in the project Materials Science-University-School Partnerships for the Design and Implementation of Research-Based ICT-Enhanced Sequences on Material Properties, Science and Society Programme, FP6, SAS6-CT-2006-042942. María Isabel Hernández was also supported by the Spanish Ministry of Science and Innovation (MICIIN) under the FPU program. The people and the organizations involved in this study are warmly thanked for allowing their daily routines to be disturbed during the research.
Author information
Authors and Affiliations
Corresponding author
Electronic supplementary material
Below is the link to the electronic supplementary material.
Rights and permissions
About this article
Cite this article
Hernández, M.I., Couso, D. & Pintó, R. Analyzing Students’ Learning Progressions Throughout a Teaching Sequence on Acoustic Properties of Materials with a Model-Based Inquiry Approach. J Sci Educ Technol 24, 356–377 (2015). https://doi.org/10.1007/s10956-014-9503-y
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10956-014-9503-y
Keywords
- Model-based inquiry
- Learning progressions
- Design-based research
- Acoustic properties of materials
- Secondary school
- Teaching–learning sequence