Abstract
Curriculum developers and researchers have promoted context-based programmes to arrest waning student interest and participation in the enabling sciences at high school and university. Context-based programmes aim for connections between scientific discourse and real-world contexts to elevate curricular relevance without diminishing conceptual understanding. Literature relating to context-based approaches to learning will be reviewed in this chapter. In particular, international trends in curricular development and results from evaluations of major projects (e.g. PLON, Salters Advanced Chemistry, ChemCom) will be highlighted. Research projects that explore context-based interventions focusing on such outcomes as student interest, perceived relevance and conceptual understanding also will feature in the review. The chapter culminates with a discussion of current context-based research that interprets classroom actions from a dialectical socio-cultural framework, and identifies possible new directions for research.
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References
American Chemical Society [ACS]. (2001). Chemistry in context (3rd ed.). New York: McGraw Hill.
Barber, M. (2000). A comparison of NEAB and Salters A-level chemistry: Student views and achievement. Unpublished MA thesis, University of York, York.
Barker, V., & Millar, R. (2000). Student’s reasoning about basic chemical thermodynamics and chemical bonding: What changes occur during a context-based post-16 chemistry course? International Journal of Science Education, 22, 1171–1200.
Barton, A. C., Furman, M., Muir, B., Barnes, J., & Monaco, S. (2007). Working on the margins to bring science to the center of students’ lives. In S. M. Ritichie (Ed.), Research collaboration: Relationships and praxis (pp. 173–187). Rotterdam, the Netherlands: Sense Publishers.
Beach, K. (2003). Consequential transitions: A developmental view of knowledge propagation through social organisations. In T. Tuomi-Grohn & Y. Engestrom (Eds.), Between school and work: New perspectives on transfer and boundary-crossing (pp. 39–61). Amsterdam: Pergamon.
Beasley, W., & Butler, J. (2002, July). Implementation of context-based science within the freedoms offered by Queensland schooling. Paper presented at the annual meeting of the Australasian Science Education Research Association Conference, Townsville, Queensland.
Bennett, J., & Lubben, F. (2006). Context-based chemistry: The Salters approach. International Journal of Science Education, 28, 999–1015.
Bennett, J., Lubben, F., & Hogarth, S. (2007). Bringing science to life: A synthesis of the research evidence on the effects of context-based and STS approaches to science teaching. Science Education, 91, 347–370.
Boud, D., & Feletti, G. (1998). The challenge of problem-based learning (2nd ed.). London: Kogan Page.
Bourdieu, P. (1990). The logic of practice. Cambridge, UK: Polity Press.
Bulte, A. M. W., Westbroek, H. B., de Jong, O., & Pilot, A. (2006). A research approach to designing chemistry education using authentic practices as contexts. International Journal of Science Education, 28, 1063–1086.
Eijekelhof, H. M. C., & Kortland, K. (1988). Broadening the aims of physics education. In P. Fensham (Ed.), Development and dilemmas in science education (pp. 282–305). Philadelphia: Falmer Press.
Eijekelhof, H. M. C., & Lijnse, P. (1988). The role of research and development to improve STS education: Experiences from the PLON project. International Journal of Science Education, 10, 464–474.
Gilbert, J. K. (2006). On the nature of “context” in chemical education. International Journal of Science Education, 28, 957–976.
Grenfell, M. J. (2007). Pierre Bourdieu education and training. London: Biddles.
Gutwill-Wise, J. (2001). The impact of active and context-based learning in introductory chemistry courses: An early evaluation of the modular approach. Journal of Chemical Education, 77, 684–690.
Hart, C. (1997, July). How the examination shapes the subject: The case of VCE physics. Paper presented at the annual meeting of the Australasian Science Education Research Association, Adelaide, South Australia.
Hofstein, A., & Kesner, M. (2006). Industrial chemistry and school chemistry: Making chemistry studies more relevant. International Journal of Science Education, 28, 1017–1039.
Hofstein, A., Kesner, M., & Ben-Zvi, R. (2000). Student perceptions of industrial chemistry classroom learning environments. Learning Environments Research, 2, 291–306.
King, D. (2007). Teachers’ beliefs and constraints in implementing a context-based approach in chemistry. Teaching Science: Journal of the Australian Science Teachers Association, 53(1), 14–18.
King, D. (2008, July). Learning in a context-based program: A dialectical socio-cultural perspective. Paper presented at the annual meeting of the Australasian Science Education Research Association, Brisbane, Queensland.
King, D., Bellocchi, A., & Ritchie, S. (2008). Making connections: Learning and teaching in context. Research in Science Education, 38, 365–384.
Lange, B., & Parchmann, I. (2003). Research to develop subject specific knowledge for students in instruction based on Chemie im Kontext. In A. Pitton (Ed.), Auberschulisches Lernen in Physik und Chemie Proceedings of the GDCP Meeting 2002 [Junior school learning in physics and chemistry] (pp. 269–271). Munster, Germany: LIT Verlag.
Lucas, K. (2002). Implementation of the chemistry trial-pilot senior syllabus. Unpublished interim report prepared for the science advisory committee, Queensland Board of Senior Secondary School Studies, Brisbane, Queensland.
Parchmann, I., Grasel, C., Baer, A., Nentwig, P., Demuth, R., Ralle, B., et al. (2006). “Chemie im Kontext”: A symbiotic implementation of a context-based teaching and learning approach. International Journal of Science Education, 28, 1041–1062.
Pilot, A., & Bulte, M. W. (2006). The use of “contexts” as a challenge for the chemistry curriculum: Its successes and the need for further development and understanding. International Journal of Science Education, 28, 1087–1111.
Pfundt, H., & Duit, R. (1997). Bibliography: Students’ alternative frameworks and science education. Kiel, Germany: Kiel University.
Ramsden, J. M. (1992). If it’s enjoyable, is it science? School Science Review, 73(265), 65–71.
Ramsden, J. M. (1994). Context and activity-based science in action. School Science Review, 75(272), 7–14.
Ramsden, J. M. (1997). How does a context-based approach influence understanding of key chemical ideas at 16+? International Journal of Science Education, 19, 697–710.
Ritchie, S. M., & Rigano, D. L. (1996). Laboratory apprenticeship through a student research project. Journal of Research in Science Teaching, 33, 799–815.
Sewell, W. H. (1992). A theory of structure: Duality, agency and transformation. American Journal of Sociology, 98, 1–29.
Sutman, F., & Bruce, M. (1992). Chemistry in the community – ChemCom: A five year evaluation. Journal of Chemical Education, 69, 564–567.
Tytler, R. (2007). Re-imagining science education: Engaging students in science for Australia’s future. Camberwell, Victoria: ACER Press.
University of York Science Education Group [UYSEG]. (2000). Salters advanced chemistry, chemical storylines, chemical ideas, activities and assessment and teachers’ guide (2nd ed.). York, UK: Heinemann Educational.
Vignouli, V., Hart, C., & Fry, M. (2002). What does it mean to teach physics ‘in context’? A second case study. Australian Science Teachers Journal, 48(3), 6–13.
Whitelegg, E., & Parry, M. (1999). Real-life contexts for learning physics: Meanings, issues and practice. Physics Education, 34(2), 68–73.
Wierstra, R. F. A. (1984). A study on classroom environment and on cognitive and affective outcomes of the PLON-curriculum. Studies in Educational Evaluation, 10, 273–282.
Wierstra, R. F. A. (1990). Natuurkunde ondeerwijs tussen leefwereld en vakstructuur [Teaching physics between then daily life world of pupils and the world of theoretical concepts]. Utrecht, the Netherlands: Uitgeverij CBD Press.
Wierstra, R. F. A., & Wubbels, T. (1992). Reality centredness of the classroom learning environment and effects on students in physics education. In H. C. Waxman & C. D. Ellett (Eds.), The study of learning environment (vol. 5, pp. 57–69). Houston, TX: The University of Houston.
Wierstra, R. F. A., & Wubbels, T. (1994). Student perception and appraisal of the learning environment: Core concepts in the evaluation of the PLON physics curriculum. Studies in Educational Evaluation, 20, 437–455.
Wilkinson, J. (1999). The contextual approach to teaching physics. Australian Science Teachers Journal, 45(4), 43–50.
Winther, A. A., & Volk, T. L. (1994). Comparing achievement of inner-city high school students in traditional versus STS- based chemistry courses. Journal of Chemical Education, 71, 501–505.
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King, D., Ritchie, S.M. (2012). Learning Science Through Real-World Contexts. In: Fraser, B., Tobin, K., McRobbie, C. (eds) Second International Handbook of Science Education. Springer International Handbooks of Education, vol 24. Springer, Dordrecht. https://doi.org/10.1007/978-1-4020-9041-7_6
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