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Philosophy of Chemistry and Chemistry Education

  • Sibel Erduran
  • Ebru Kaya
Chapter
Part of the Science: Philosophy, History and Education book series (SPHE)

Abstract

The chapter provides the background to why it is important to include epistemic themes in chemistry pre-service teacher education. It includes an introduction to the book by reviewing the literature on philosophy of chemistry and its broad implications for chemistry education. Philosophy of chemistry is the disciplinary context for the consideration of epistemic issues in chemistry. It is a relatively new area within philosophy of science having been formalised with its own journals and conferences since the 1990s. Although research at the intersection of philosophy of chemistry and chemistry education has begun to emerge, the focus on chemistry teacher education is practically non-existent in the literature. The review of the interplay between philosophy of chemistry and chemistry education suggests that the recommendations are fairly abstract for the pragmatic purposes of chemistry teacher education and do not take into consideration the empirical evidence on how pre-service teachers learn. In order to focus the discussion on some concise and useful ideas on what epistemic aspects of chemistry could be included in teacher education practice, we propose a framework consisting of the epistemic aims and values, practices, methods and knowledge of science. These components are collectively referred to as the “epistemic core”. The potential benefits of teaching and learning of the epistemic core are discussed, and a summary of the whole book is presented.

References

  1. Aduriz-Bravo, A. (2013). A ‘semantic’ view of scientific models for science education. Science & Education, 22(7), 1593–1611.Google Scholar
  2. Akgun, S. (2018). University students’ understanding of the nature of science. Unpublished Master’s thesis. Bogazici University, Istanbul, Turkey.Google Scholar
  3. Alayoglu, M. (2018). Fifth-grade students’ attitudes towards science and their understanding of its social-institutional aspects. Unpublished Master’s thesis. Bogazici University, Istanbul, Turkey.Google Scholar
  4. Aubusson, P., Treagust, D., & Harrison A. (2009). Learning and teaching science with analogies and metaphors. In The world of science education: Handbook of research in Australasia. Rotterdam, The Netherlands: Sense Publishers.Google Scholar
  5. Avraamidou, L. (2014). Studying science teacher identity: Current insights and future research directions. Studies in Science Education, 50(2), 145–179.Google Scholar
  6. Baird, D., Scerri, E., & McIntyre, L. (2006). Introduction: The invisibility of chemistry. In D. Baird, E. Scerri, & L. McIntyre (Eds.), Philosophy of chemistry: Synthesis of a new discipline. Dordrecht, The Netherlands: Springer.Google Scholar
  7. BouJaoude, S., Dagher, Z., & Refai, S. (2017). The portrayal of nature of science in Lebanese ninth grade science textbooks. In C. V. McDonald & F. Abd-el-Khalick (Eds.), Representations of nature of science in school science textbooks: A global perspective (pp. 79–97). New York: Routledge.Google Scholar
  8. Chamizo, J. A. (1992). La química en secundaria, o por qué la enseñanza moderna de la química no es la enseñanza de la química moderna [Chemistry in junior high school, or why modern teaching of chemistry is not modern chemistry teaching]. Información Científica y Tecnológica, 14, 49–51.Google Scholar
  9. Chamizo, J. A. (2013). A new definition of models and modeling in chemistry’s teaching. Science & Education, 22(7), 1613–1632.Google Scholar
  10. Chamizo, J. A. (2014). The role of instruments in three chemical’ revolutions. Science Education, 23, 955–982.Google Scholar
  11. Coenders, S. F., Terlouw, C., Dijkstra, S., & Pieters, J. (2010). The effects of the design and development of a chemistry curriculum reform on teachers’ professional growth: A case study. Journal of Science Teacher Education, 21, 535–557.Google Scholar
  12. Conant, J. B. (1947). On understanding science. New Haven, CT: Yale University Press.Google Scholar
  13. Conant, J. B. (1948). Harvard case histories of experimental science. Cambridge, MA: Harvard University Press.Google Scholar
  14. Cooper, M. (2018). Chemistry education research- from personal empiricism to evidence, theory and informed practice. Chemical Reviews, 118(12), 6053–6087.Google Scholar
  15. Cullinane, A. (2018). Incorporating nature of science in initial science teacher education. Unpublished PhD dissertation. University of Limerick, Ireland.Google Scholar
  16. Dagher, Z., & Erduran, S. (2016). Reconceptualizing the nature of science: Why does it matter? Science & Education, 25(1 & 2), 147–164.Google Scholar
  17. Dagher, Z., & Erduran, S. (2017). Abandoning patchwork approaches to nature of science in science education. Canadian Journal of Science, Mathematics and Technology Education, 17(1), 46–52.Google Scholar
  18. Duschl, R. (1990). Restructuring science education: The importance of theories and their development. New York: Teachers College Press.Google Scholar
  19. Duschl, R., Erduran, S., Grandy, R., & Rudolph, J. (2006). Guest editorial: Science studies and science education. Science Education, 90(6), 961–964.Google Scholar
  20. Early, J. E. (2013). A new ‘idea of nature’ for chemical education. Science & Education, 22(7), 1775–1786.Google Scholar
  21. Eilam, B., & Gilbert, J. K. (2014). Science teachers’ use of visual representations. Dordrecht, The Netherlands: Springer.Google Scholar
  22. Ellis, V., Blake, A., McNicholl, J., & McNally, J. (2011). The work of teacher education: The final research report for the Higher Education Academy, Subject Centre for Education. ESCalate.Google Scholar
  23. Erduran, S. (2001). Philosophy of chemistry: An emerging field with implications for chemical education. Science & Education, 10, 581–593.Google Scholar
  24. Erduran, S. (2005). Applying the philosophical concept of reduction to the chemistry of water: Implications for chemical education. Science & Education, 14(2), 161–171.Google Scholar
  25. Erduran, S. (2007). Breaking the law: Promoting domain-specificity in science education in the context of arguing about the periodic law in chemistry. Foundations of Chemistry, 9(3), 247–263.Google Scholar
  26. Erduran, S. (2009). Beyond philosophical confusion: Establishing the role of philosophy of chemistry in chemical education research. Journal of Baltic Science Education, 8(10), 5–14.Google Scholar
  27. Erduran, S. (2013). Editorial: Philosophy, chemistry and education: An introduction. Science & Education, 22, 1559.Google Scholar
  28. Erduran, S. (2014). Beyond nature of science: The case for reconceptualising ‘science’ for science education. Science Education International, 25(1), 93–111.Google Scholar
  29. Erduran, S. (2017). Visualising the nature of science: Beyond textual pieces to holistic images in science education. In K. Hahl, K. Juuti, J. Lampiselkä, J. Lavonen, & A. Uitto (Eds.), Cognitive and affective aspects in science education research: Selected papers from the ESERA 2015 conference (pp. 15–30). Dordrecht, The Netherlands: Springer.Google Scholar
  30. Erduran, S., & Dagher, Z. (2014a). Reconceptualizing the nature of science for science education: Scientific knowledge, practices and other family categories. Dordrecht, The Netherlands: Springer.Google Scholar
  31. Erduran, S., & Dagher, Z. (2014b). Regaining focus in Irish junior cycle science: Potential new directions for curriculum development on nature of science. Irish Educational Studies, 33(4), 335–350.Google Scholar
  32. Erduran, S., & Jimenez-Aleixandre, M. P. (Eds.). (2007). Argumentation in science education: Perspectives from classroom-based research. Dordrecht, The Netherlands: Springer.Google Scholar
  33. Erduran, S., & Kaya, E. (2018). Drawing nature of science in pre-service science teacher education: Epistemic insight through visual representations. Research in Science Education, 48(6), 1133–1149.Google Scholar
  34. Fernandez-Gonzalez, M. (2013). Idealization in chemistry: Pure substance and laboratory product. Science & Education, 22(7), 1723–1740.Google Scholar
  35. Gabel, D., & Bunce, D. (1984). Research on problem solving in chemistry. In D. Gabel (Ed.), Handbook of research on science teaching and learning (pp. 301–326). New York: Macmillan Publishing Company.Google Scholar
  36. Garritz, A. (2013). Teaching the philosophical interpretations of quantum mechanics and quantum chemistry through controversies. Science & Education, 22(7), 1787–1807.Google Scholar
  37. Gilbert, J., & Boulter, C. (2000). Developing models in science education. Dordrecht, The Netherlands: Kluwer Academic.Google Scholar
  38. Gilbert, J. K. (2006). On the nature of “context” in chemical education. International Journal of Science Education, 28, 957–976.Google Scholar
  39. Gilbert, J. K., de Jong, O., Justi, R., Treagust, D. F., & van Driel, J. H. (2003). Research and development for the future of chemical education. In J. K. Gilbert, O. De Jong, R. Justi, D. F. Tragust, & J. H. van Driel (Eds.), Chemical education: Towards research based practice (pp. 391–408). Dordrecht, The Netherlands: Kluwer.Google Scholar
  40. Good, R. J. (1999). Why are chemists turned off by philosophy? Foundations of Chemistry, 1, 65–96.Google Scholar
  41. Greene, J. A., Sandoval, W. A., & Braten, I. (2016). Handbook of epistemic cognition. New York: Routledge.Google Scholar
  42. Gunstone, R. F. (1991). Constructivism and metacognition: Theoretical issues and classroom studies. In R. Duit, F. Goldberg, & H. Niedderer (Eds.), Research in physics learning: Theoretical issues and empirical studies (pp. 129–140). Kiel, Germany: Institute of Science Education.Google Scholar
  43. Hewson, P. W., & Hewson, M. G. (1984). The role of conceptual conflict in conceptual change and the design of science instruction. Instructional Science, 13(1), 1–13.Google Scholar
  44. Hodson, D. (1988). Towards a philosophically more valid science curriculum. Science Education, 72, 19–40.Google Scholar
  45. Hodson, D. (2011). Looking to the future: Building a curriculum for social activism. Rotterdam, The Netherlands: Sense Publishers.Google Scholar
  46. Hoffman, R., Minkin, V. I., & Carpenter, B. K. (1997). Ockham’s razor and chemistry. Hyle – An International Journal for the Philosophy of Chemistry, 3, 3–28.Google Scholar
  47. Höttecke, D., & Silva, C. C. (2011). Why implementing history and philosophy in school science education is a challenge: An analysis of obstacles. Science & Education, 20, 293–316.Google Scholar
  48. Irzik, G., & Nola, R. (2011). A family resemblance approach to the nature of science for science education. Science & Education, 20, 591–607.Google Scholar
  49. Irzik, G., & Nola, R. (2014). New directions for nature of science research. In M. Matthews (Ed.), International handbook of research in history, philosophy and science teaching (pp. 999–1021). Dordrecht, The Netherlands: Springer.Google Scholar
  50. Izquierdo-Aymerich, M. (2013). School chemistry: An historical and philosophical approach. Science & Education, 22(7), 1633–1653.Google Scholar
  51. Johnstone, A. H. (1993). The development of chemistry teaching: A changing response to changing demand. Journal of Chemical Education, 70, 701–705.Google Scholar
  52. Kampourakis, K. (2016). The “general aspects” conceptualization as a pragmatic and effective means to introducing students to nature of science. Journal of Research in Science Teaching, 53(5), 667–682.Google Scholar
  53. Karabas, N. (2017). The effect of scientific practice-based instruction on seventh graders’ perceptions of scientific practices. Unpublished Master’s thesis. Bogazici University, Istanbul, Turkey.Google Scholar
  54. Kauffman, G. B. (1989). History in the chemistry curriculum. Interchange, 20(2), 81–94.Google Scholar
  55. Kaya, E., & Erduran, S. (2013). Integrating epistemological perspectives on chemistry in chemical education: The cases of concept duality, chemical language, and structural explanations. Science & Education, 22(7), 1741–1755.Google Scholar
  56. Kaya, E., & Erduran, S. (2016). From FRA to RFN, or how the family resemblance approach can be transformed for science curriculum analysis on nature of science. Science & Education, 25(9), 1115–1133.Google Scholar
  57. Kaya, E., Erduran, S., Aksoz, B., & Akgun, S. (2019). Reconceptualised family resemblance approach to nature of science in pre-service science teacher education. International Journal of Science Education, 41(1), 21–47.Google Scholar
  58. Kelly, G. J. (2011). Scientific literacy, discourse, and epistemic practices. In C. Linder, L. Östman, D. A. Roberts, P. Wickman, G. Erikson, & A. McKinnon (Eds.), Exploring the landscape of scientific literacy (pp. 61–73). New York: Routledge.Google Scholar
  59. Klopfer, L. (1969). The teaching of science and the history of science. Journal of Research in Science Teaching, 6, 87–95.Google Scholar
  60. Kuhn, D. (1999). A development model of critical thinking. Educational Researcher, 28(2), 16–46.Google Scholar
  61. Laszlo, P. (1999). Circulation of concepts. Foundations of Chemistry, 1, 225–238.Google Scholar
  62. Laszlo, P. (2013). Towards teaching chemistry as a language. Science & Education, 22(7), 1669–1706.Google Scholar
  63. Lipman, M. (1988). Critical thinking – what can it be? Educational Leadership, 46(1), 38–43.Google Scholar
  64. Lythcott, J. (1990). Problem solving and requisite knowledge of chemistry. Journal of Chemical Education, 67(3), 248–252.Google Scholar
  65. Mahaffy, P. (2006). Moving chemistry education into 3D: A tetrahedral metaphor for understanding chemistry. Journal of Chemical Education, 83(1), 49–55.Google Scholar
  66. Matthews, M. R. (2014). Science teaching. The role of history and philosophy of science. New York: Routledge.Google Scholar
  67. McDonald, C. V. (2017). Exploring representations of nature of science in Australian junior secondary school science textbooks: A case study of genetics. In C. V. McDonald & F. Abd-el-Khalick (Eds.), Representations of nature of science in school science textbooks: A global perspective (pp. 98–117). New York: Routledge.Google Scholar
  68. McIntyre, L., & Scerri, E. (1997). The philosophy of chemistry- editorial introduction. Synthese, 111(3), 211–212.Google Scholar
  69. Newman, M. (2013). Emergence, supervenience, and introductory chemical education. Science & Education, 22(7), 1655–1667.Google Scholar
  70. Niaz, M. (1988). Manipulation of M demand of chemistry problems and its effect on student performance: A neo-Piagetian study. Journal of Research in Science Teaching, 25, 643–657.  https://doi.org/10.1002/tea.3660250804.CrossRefGoogle Scholar
  71. Niaz, M. (2011). Innovating science teacher education: A history and philosophy of science perspective. Oxon, UK: Routledge.Google Scholar
  72. Niaz, M. (2016). Chemistry education and contributions from history and philosophy of science. Dordrecht, The Netherlands: Springer.Google Scholar
  73. Pedretti, E., & Nazir, J. (2011). Currents in STSE education: Mapping a complex field. Science Education, 95, 601–626.Google Scholar
  74. Pinto-Ribeiro, M. A., & Costa-Pereira, D. (2013). Constitutive pluralism of chemistry: Thought planning, curriculum, epistemological and didactic orientations. Science & Education, 22(7), 1809–1837.Google Scholar
  75. Rice, F., & Teller, E. (1936). The role of free radicals in elementary organic reactions. Journal of Chemical Physics, 6, 489.Google Scholar
  76. Ross, B., & Munby, H. (1991). Concept mapping and misconceptions: A study of high-school students’ understanding of acids and bases. International Journal of Science Education, 13(1), 11–23.Google Scholar
  77. Sandoval, W. (2005). Understanding students’ practical epistemologies and their influence on learning through inquiry. Science Education, 89, 634–656.Google Scholar
  78. Scerri, E. (1997). Are chemistry and philosophy miscible? The Chemical Intelligencer, 3, 44–46.Google Scholar
  79. Scerri, E. (2000). Philosophy of chemistry-A new interdisciplinary field? Journal of Chemical Education, 77(4), 522–525.Google Scholar
  80. Scerri, E. R. (2007). The periodic table: Its story and its significance. New York: Oxford University Press.Google Scholar
  81. Sjöström, J. (2013). Towards Bildung-oriented chemistry education. Science & Education, 22(7), 1873–1890.Google Scholar
  82. Standen, A. (1948). Three ways of teaching chemistry. Journal of Chemical Education, 25(9), 506.Google Scholar
  83. Swennen, A., Jones, K., & Volman, M. (2010). Teacher educators: Their identities, sub-identities and implications for professional development. Professional Development in Education, 36(1–2), 131–114.Google Scholar
  84. Talanquer, V. (2013). School chemistry: The need for transgression. Science & Education, 22(7), 1757–1773.Google Scholar
  85. Teo, T. W., Goh, M. T., & Yeo, L. W. (2014). Chemistry education research trends: 2004–2013. Chemistry Education Research and Practice, 15, 470–487.Google Scholar
  86. Thalos, M. (2013). The lens of chemistry. Science & Education, 22(7), 1707–1721.Google Scholar
  87. Tobin, E. (2013). Chemical laws, idealization and approximation. Science & Education, 22(7), 1581–1592.Google Scholar
  88. Tsai, C.-C. (2004). A review and discussion of epistemological commitments, metacognition, and critical thinking with suggestions on their enhancement in internet-assisted chemistry classrooms. Journal of Chemical Education, 78(7), 970–974.Google Scholar
  89. van Brakel, J. (1997). Chemistry as the science of the transformation of substances. Synthese, 111(3), 253–282.Google Scholar
  90. van Brakel, J. (2000). Philosophy of chemistry: Between the manifest and the scientific image. Leuven, Belgium: Leuven University Press.Google Scholar
  91. van Brakel, J. (2010). A subject to think about: Essays on the history and philosophy of chemistry. Ambix, 57(2), 233–234.Google Scholar
  92. Vesterinen, V. M., Aksela, M., & Lavonen, J. (2013). Quantitative analysis of representations of nature of science in Nordic secondary school textbooks using framework of analysis based on philosophy of chemistry. Science & Education, 22(7), 1839–1855.Google Scholar
  93. Vilches, A., & Gil-Perez, D. (2013). Creating a sustainable future: Some philosophical and educational considerations for chemistry teaching. Science & Education, 22(7), 1857–1872.Google Scholar
  94. Weisberg, M., Needham, P., Hendry, R. (2011). Philosophy of chemistry. In Stanford encyclopedia of philosophy. Stanford, CA: Stanford University.Google Scholar
  95. White, R. T., & Mitchell, I. J. (1994). Metacognition and the quality of learning. Studies in Science Education, 23, 21–37.Google Scholar
  96. Woody, A. (2013). How is the ideal gas law explanatory? Science & Education, 22(7), 1563–1580.Google Scholar
  97. Zohar, A. (2012). Explicit teaching of metastrategic knowledge: Definitions, students’ learning, and teachers’ professional development. In A. Zohar & Y. J. Dori (Eds.), Metacognition in science education: Trends in current research (Vol. 40, pp. 197–223). Dordrecht, The Netherlands: Springer.Google Scholar

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© Springer Nature Switzerland AG 2019

Authors and Affiliations

  • Sibel Erduran
    • 1
  • Ebru Kaya
    • 2
  1. 1.Department of EducationUniversity of OxfordOxfordUK
  2. 2.Department of Mathematics and Science EducationBoğaziçi UniversityIstanbulTurkey

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