Abstract
Research in science education has recognized the importance of history and philosophy of science (HPS), and this has facilitated the evaluation of science textbooks. Purpose of this chapter is to review research based on analyses of science textbooks that explicitly use a history and philosophy of science framework. This review has focused on studies published in the 15-year period (1996–2010) and has drawn on the following major science education journals: International Journal of Science Education, Journal of Research in Science Teaching, Science Education, and Science & Education. Based on HPS-related criteria, 52 articles were selected for review, and of these 28 were published in Science & Education, which clearly shows the importance of HPS for this journal. Selected articles were classified in the following subject areas depending on the textbooks analyzed: university biology textbooks (n = 2), university chemistry textbooks (n = 14), university physics textbooks (n = 17), and primary, secondary, and high school textbooks (n = 19). Results obtained revealed the following: (a) Most biology, chemistry, physics, and school science textbooks lack a history and philosophy of science perspective; (b) most of the textbooks analyzed were published in the USA and to a much lesser extent in other countries; (c) few studies provided details of the procedure and reliability of the application of criteria/rubric for analyzing textbooks; (d) some of the topics analyzed in the textbooks were nature of science, atomic structure, Newtonian mechanics, quantum mechanics, special theory of relativity, and evolution; (e) textbooks avoided including controversial and difficult aspects of different topics (e.g., concepts of force, weight, heat, temperature, origin of the quantum hypothesis, oil drop experiment, Millikan’s data supported Einstein’s photoelectric equation but not his theory); and (f) various science topics provide an opportunity to illustrate the tentative nature of scientific knowledge, and still very few textbooks referred to this important aspect. As textbooks do refer to laws and theories while referring to historical content, it is concluded that HPS is already “inside” the science curriculum provided textbook authors make an effort to scrutinize the historical reconstructions while dealing with the different topics.
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References
Abd-El-Khalick, F. (2005). Developing deeper understandings of nature of science: The impact of a philosophy of science course on preservice science teachers’ views and instructional planning. International Journal of Science Education, 27, 15–42.
Abd-El-Khalick, F., Waters, M., & Le, A. (2008). Representation of nature of science in high school chemistry textbooks over the past four decades. Journal of Research in Science Teaching, 45(7), 835–855.
American Association for the Advancement of Science, AAAS (1989). Project 2061: Science for all Americans. Washington, DC: AAAS.
American Association for the Advancement of Science, AAAS (1993). Benchmarks for science literacy: Project 2061. New York: Oxford University Press.
Arriassecq, I., & Greca, I.M. (2007). Approaches to the teaching of special relativity theory in high school and university textbooks of Argentina. Science & Education, 16(1), 65–86.
Assis, A.K.T., & Zylbersztajn, A. (2001). The influence of Ernst Mach in the teaching of mechanics. Science & Education, 10(1–2), 137–144.
Barberá, O., Zanón, B., & Pérez-Plá, J.F. (1999). Biology curriculum in twentieth century Spain. Science Education, 83(1), 97–111.
Bensaude-Vincent, B. (2006). Textbooks on the map of science studies. Science & Education, 15, 667–670.
Bevilacqua, F., & Bordoni, S. (1998). New contents for new media: Pavia project physics. Science & Education, 7, 451–469.
Brito, A., Rodríguez, M.A., & Niaz, M. (2005). A reconstruction of development of the periodic table based on history and philosophy of science and its implications for general chemistry textbooks. Journal of Research in Science Teaching, 42(1), 84–111.
Brush, S.G. (1976). The kind of motion we call heat: A history of the kinetic theory of gases in the 19th century. New York: North-Holland.
Brush, S.G. (1989). History of science and science education. Interchange, 9, 39–58.
Brush, S.G. (2000). Thomas Kuhn as a historian of science. Science & Education, 9(1–2), 39–58.
Bybee, R. W. (1989). Teaching high school biology: Materials and strategies, In W. G. Rosen (Ed.), High school biology today and tomorrow (pp. 165–177). Washington, DC: National Academy Press.
Campbell, N.A., & Reece, J.B. (2005). Biology (7th ed.). San Francisco: Pearson.
Chiappetta, E.L., Ganesh, T.G., Lee, Y.H., & Phillips, M.C. (2006, April). Examination of science textbook analysis research conducted on textbooks published over the past 100 years in the United States. Paper presented at the Annual Conference of the National Association for Research in Science Teaching (NARST), San Francisco.
Chiappetta, E.L., & Fillman, D.A. (2007). Analysis of five high school biology textbooks used in the United States for inclusion of the nature of science, International Journal of Science Education, 29(15), 1847–1868.
Cobern, W.W. (1996). Worldview theory and conceptual change in science education. Science Education, 80(5), 579–610.
Coelho, R.L. (2010). On the concept of force: How understanding its history can improve physics teaching. Science & Education, 19(1), 91–113.
Cooper, L.N. (1970). An introduction to the meaning and structure of physics (short edition). New York: Harper & Row.
Cotignola, M.I., Bordogna, C., Punte, G., & Cappannini, O.M. (2002). Difficulties in learning thermodynamic concepts: Are they linked to the historical development of this field? Science & Education, 11(3), 279–291.
Cushing, J.T. (1991). Quantum theory and explanatory discourse: Endgame for understanding. Philosophy of Science, 58, 337–358.
Dagher, Z.R., & Ford, D.J. (2005). How are scientists portrayed in children’s science biographies? Science & Education, 14(3–5), 377–393.
De Berg, K.C. (2006). The kinetic-molecular and thermodynamic approaches to osmotic pressure: A study of dispute in physical chemistry and the implications for chemistry education. Science & Education, 15(5), 495–519.
De Berg, K.C. (2008a). The concepts of heat and temperature: The problem of determining the content for the construction of an historical case study which is sensitive to nature of science issues and teaching-learning issues. Science & Education, 17(1), 75–114.
De Berg, K.C. (2008b). Tin oxide chemistry from Macquer (1758) to Mendeleeff (1891) as revealed in the textbooks and other literature of the era. Science & Education, 17(2–3), 265–287.
De Posada, J.M. (1999). The presentation of metallic bonding in high school science textbooks during three decades: Science educational reforms and substantive changes of tendencies. Science Education, 83, 423–447.
Dybowski, C.R. (2001). A course in the history of physical chemistry with an emphasis on writing. Journal of Chemical Education, 78(12), 1623–1625.
Feynman, R.P. (1994). Six easy pieces. Reading, MA: Helix Books.
Flodin, V.S. (2009). The necessity of making visible concepts with multiple meanings in science education: The use of the gene concept in a biology textbook. Science & Education, 18(1), 73–94.
Furió, C., Azcona, R., Guisasola, J., & Ratcliffe, M. (2000). Difficulties in teaching the concepts of ‘amount of substance’ and ‘mole’. International Journal of Science Education, 22(12), 1285–1304.
Furió-Más, C., Calatayud, M.L., Guisasola, J., & Furió-Gómez, C. (2005). How are the concepts and theories of acid–base reactions presented? Chemistry in textbooks and as presented by teachers. International Journal of Science Education, 27(11), 1337–1358.
Galili, I. (2001). Weight versus gravitational force: Historical and educational perspectives. International Journal of Science Education, 23(10), 1073–1093.
Galili, I., & Tseitlin, M. (2003). Newton’s first law: Text, translations, interpretations and physics education. Science & Education, 12(1), 45–73.
Gardner, P.L. (1999). The representation of science-technology relationships in Canadian physics textbooks. International Journal of Science Education, 21(3), 329–347.
Gericke, N.M., & Hagberg, M. (2010). Conceptual variation in the depiction of gene function in upper secondary school textbooks. Science & Education, 19(10), 963–994.
German, P.J., Haskins, S., & Auls, S. (1996). Analysis of nine high school biology laboratory manuals: Promoting scientific inquiry. Journal of Research in Science Teaching, 33(5), 475–499.
Gilbert, J.K., & Reiner, M. (2000). Thought experiments in science education: Potential and current realization. International Journal of Science Education, 22(3), 265–283.
Gooday, G., Lynch, J.M., Wilson, K.G., & Barsky, C.K. (2008). Does science education need the history of science? Isis, 99, 322–330.
Guisasola, J., Almudía, J.M., & Furió, C. (2005). The nature of science and its implications for physics textbooks: The case of classical magnetic field theory. Science & Education, 14(3–5), 321–338.
Hodson, D. (1985). Philosophy of science, science, and science teaching. Studies in Science Education, 12, 25–57.
Hodson, D. (1988). Toward a philosophically more valid science curriculum. Science Education, 72, 19–40.
Hodson, D. (2008). Towards Scientific Literacy: A Teachers Guide to the History, Philosophy and Sociology of Science. Rotterdam: Sense Publishers.
Hodson, D. (2009). Teaching and learning about science: Language, theories, methods, history, traditions and values. Rotterdam: Sense Publishers.
Hofmann, J.R., & Weber, B.H. (2003). The fact of evolution: Implications for science education. Science & Education, 12(8), 729–760.
Holton, G. (1952). Introduction to concepts and theories in physical science. New York: Addison-Wesley.
Holton, G. (1969). Einstein and ‘crucial’ experiments. American Journal of Physics, 37(10), 968–982.
Holton, G. (1978). Subelectrons, presuppositions, and the Millikan-Ehrenhaft dispute. Historical Studies in the Physical Sciences, 9, 161–224.
Holton, G. (2000). Personal communication, September.
Holton, G. (2003). The project physics course, then and now. Science & Education, 12, 779–786.
Holton, G., & Brush, S.G. (2001). Physics, the human adventure: From Copernicus to Einstein and beyond (3rd ed.) New Brunswick, NJ: Rutgers University Press.
Hosson, C., & Kaminski, W. (2007). Historical controversy as an educational tool: Evaluating elements of a teaching-learning sequence conducted with the text “Dialogues on the ways that vision operates.” International Journal of Science Education, 29, 617–642.
Irez, S. (2009). Nature of science as depicted in Turkish biology textbooks. Science Education, 93, 422–447.
Justi, R.S., & Gilbert, J.K. (2000). History and philosophy of science through models: Some challenges in the case of ‘the atom’. International Journal of Science Education, 22, 993–1009.
Kindi, V. (2005). Should science teaching involve the history of science? An assessment of Kuhn’s view. Science & Education, 14, 721–731.
Klassen, S. (2009). Identifying and addressing student difficulties with the Millikan oil drop experiment. Science & Education, 18, 593–607.
Klopfer, L.E. (1969). The teaching of science and the history of science. Journal of Research in Science Teaching, 6, 87–95.
Knain, E. (2001). Ideologies in school science textbooks. International Journal of Science Education, 23(3), 319–329.
Koliopoulos, D., & Constantinou, C. (2005). The pendulum as presented in school science textbooks of Greece and Cyprus. Science & Education, 14(1), 59–73.
Kragh, H.A. (1992). Sense of history: History of science and the teaching of introductory quantum theory. Science & Education, 1, 349–363.
Kragh, H. (1999). Quantum generations: A history of physics in the twentieth century. Princeton, NJ: Princeton University Press.
Kubli, F. (2005). Science teaching as a dialogue --- Bakhtin, Vygotsky and some applications in the classroom. Science & Education, 14, 501–534.
Kuhn, T.S. (1977). The function of measurement in modern physical research (first published in 1961). In T.S. Kuhn (Ed.), The essential tension (pp. 178–224). Chicago: University of Chicago Press.
Kuhn, T.S. (1978). Black-body theory and the quantum discontinuity: 1894–1912. New York: Oxford University Press.
Lakatos, I. (1970). Falsification and the methodology of scientific research programmes. In I. Lakatos & A. Musgrave (Eds), Criticism and the growth of knowledge (pp. 91–195). Cambridge, UK: Cambridge University Press.
Lederman, N.G., McComas, W.F., & Matthews, M.R. (1998). Editorial. Science & Education, 7(6), 507–509.
Leite, L. (2002). History of science in science education: Development and validation of a checklist for analyzing the historical content of science textbooks. Science & Education, 11(4), 333–359.
Lewis, G.N. (1916). The atom and the molecule. Journal of American Chemical Society, 38, 762–785.
Linn, M.C., Songer, N.B., & Lewis, E.L. (1991). Overview: Students’ models and epistemologies of science. Journal of Research in Science Teaching, 28, 729–732.
Mach, E. (1960). The science of mechanics --- A critical and historical account of its development. La Salle, IL: Open Court.
Machamer, P., Pera, M., & Baltas, A. (2000). Scientific controversies: An introduction. In P. Machamer, M. Pera & A. Baltas (Eds.), Scientific controversies: Philosophical and historical perspectives (pp. 3–17). New York: Oxford University Press.
Matthews, M.R. (1990). History, philosophy, and science teaching: A rapprochement. Studies in Science Education, 18, 25–51.
Matthews, M.R. (1994/2014). Science teaching: The contribution of history and philosophy of science.New York: Routledge.
Matthews, M.R. (1998). In defense of modest goals when teaching about the nature of science. Journal of Research in Science Teaching, 35, 161–174.
Matthews, M.R. (2000). Time for science education. New York: Kluwer/Plenum.
Matthews, M.R., Gauld, C.F., & Stinner, A. (2005). Eds., The pendulum: Scientific, historical, philosophical and educational perspective. Dordrecht, The Netherlands: Springer.
Mayr, E. (1997). This is biology. Cambridge, MA: Harvard University Press (Belnap).
Mendeleev, D. (1889). The periodic law of the chemical elements (Faraday lecture, delivered on 4 June, 1889). Journal of the Chemical Society, 55, 634–656.
Millikan, R.A. (1916). A direct photoelectric determination of Planck’s h. Physical Review, 7, 355–388.
Milne, C. (1998). Philosophically correct science stories? Examining the implications of heroic science stories for school science. Journal of Research in Science Teaching, 35(2), 175–187.
Milne, C. (1999). “Only some facts matter for my given pattern”: The fact of stories in school science. A response to Whitaker. Journal of Research in Science Teaching, 36(10), 1155–1157.
Moody, D.E. (1996). Evolution and the textbook structure of biology. Science Education, 80(4), 395–418.
National Research Council, NRC (1996). National science education standards. Washington, DC: National Academy Press.
Niaz, M. (1998). From cathode rays to alpha particles to quantum of action: A rational reconstruction of structure of the atom and its implications for chemistry textbooks. Science Education, 82, 527–552.
Niaz, M. (2000a). The oil-drop experiment: A rational reconstruction of the Millikan-Ehrenhaft controversy and its implications for chemistry textbooks. Journal of Research in Science Teaching, 37, 480–508.
Niaz, M. (2000b). A rational reconstruction of the kinetic molecular theory of gases based on history and philosophy of science and its implications for chemistry textbooks. Instructional Science, 28(1), 23–50.
Niaz, M. (2001a). How important are the laws of definite and multiple proportions in chemistry and teaching chemistry? A history and philosophy of science perspective. Science & Education, 10, 243–266.
Niaz, M. (2001b). A rational reconstruction of the origin of the covalent bond and its implications for general chemistry textbooks. International Journal of Science Education, 23(6), 623–641.
Niaz, M. (2008). Teaching general chemistry: A history and philosophy of science approach. New York: Nova Science Publishers.
Niaz, M. (2009a). Critical appraisal of physical science as a human enterprise: Dynamics of scientific progress. Dordrecht, The Netherlands: Springer.
Niaz, M. (2009b). Progressive transitions in chemistry teachers’ understanding of nature of science based on historical controversies. Science & Education, 18, 43–65.
Niaz, M. (2010a). Science curriculum and teacher education: The role of presuppositions, contradictions, controversies and speculations vs Kuhn’s ‘normal science.’ Teaching and Teacher Education, 26, 891–899.
Niaz, M. (2010b). Are we teaching science as practiced by scientists? American Journal of Physics, 78(1), 5–6.
Niaz, M. (2011). Innovating science teacher education: A history and philosophy of science perspective. New York: Routledge.
Niaz, M., & Coştu, B. (2009). Presentation of atomic structure in Turkish general chemistry textbooks. Chemistry Education Research and Practice, 10, 233–240.
Niaz, M., & Fernández, R. (2008). Understanding quantum numbers in general chemistry textbooks. International Journal of Science Education, 30(7), 869–901.
Niaz, M., Klassen, S., McMillan, B., & Metz, D. (2010a). Reconstruction of the history of the photoelectric effect and its implications for general physics textbooks. Science Education, 94, 903–931.
Niaz, M., Klassen, S., McMillan, B., & Metz, D. (2010b). Leon Cooper’s perspective on teaching science: An interview study. Science & Education, 19(1), 39–54.
Niaz, M., & Marcano, C. (2012). Reconstruction of wave-particle duality and its implications for general chemistry textbooks. Dordrecht, The Netherlands: Springer Briefs in Education.
Niaz, M., & Maza, A. (2011). Nature of science in general chemistry textbooks. Dordrecht, The Netherlands: Springer Briefs in Education.
Niaz, M., & Rodríguez, M.A. (2001). Do we have to introduce history and philosophy of science or is it already ‘inside’ chemistry? Chemistry Education: Research and Practice in Europe, 2, 159–164.
Niaz, M., & Rodríguez, M.A. (2005). The oil drop experiment: Do physical chemistry textbooks refer to its controversial nature? Science & Education, 14, 43–57.
Niss, M. (2009). Metamodelling messages conveyed in five statistical mechanical textbooks from 1936 to 2001. International Journal of Science Education, 31(5), 697–719.
Padilla, K., & Furio-Mas, C. (2008). The importance of history and philosophy of science in correcting distorted views of ‘amount of substance’ and ‘mole’ concepts in chemistry teaching. Science & Education, 17(4), 403–424.
Planck, M. (1900). Zur theorie des gesetzes der energieverteilung im normalspectrum. Verhandlungen der Deutschen Physikalische Gesellschaft, 2, 237–245.
Pocoví, M.C. (2007). The effects of a history-based instructional material on the students’ understanding of field lines. Journal of Research in Science Teaching, 44, 107–132.
Pocoví, M.C., & Finley, F.N. (2003). Historical evolution of the field view and textbook accounts. Science & Education, 12(4), 387–396.
Polanyi, M. (1964). Personal knowledge. Chicago: University of Chicago Press (first published 1958).
Posner, G.J., Strike, K.A., Hewson, P.W., & Gertzog, W.A. (1982). Accommodation of a scientific conception: Toward a theory of conceptual change. Science Education, 66, 211–227.
Reinmuth, O. (1932). Editor’s outlook. Journal of Chemical Education, 9, 1139–1140.
Roberts, L. (2001). The human genome. Science, 2991(5507), 1177–1188.
Robinson, J.T. (1969). Philosophy of science: Implications for teacher education. Journal of Research in Science Teaching, 6, 99–104.
Rodríguez, M.A., & Niaz, M. (2002). How in spite of the rhetoric, history of chemistry has been ignored in presenting atomic structure in textbooks. Science & Education, 11(5), 423–441.
Rodríguez, M.A., & Niaz, M. (2004a). A reconstruction of structure of the atom and its implications for general physics textbooks. Journal of Science Education and Technology, 13, 409–424.
Rodríguez, M.A., & Niaz, M. (2004b). The oil drop experiment: An illustration of scientific research methodology and its implications for physics textbooks. Instructional Science, 32, 357–386.
Rutherford, E. (1911). The scattering of alpha and beta particles by matter and the structure of the atom. Philosophical Magazine, 21, 669–688.
Scheffler, I. (1992). Philosophy and the curriculum. Science and Education, 1(4), 385–394.
Schwab, J.J. (1962). The teaching of science as enquiry. Cambridge, MA: Harvard University Press.
Schwab, J.J. (1974). The concept of the structure of a discipline. In E.W. Eisner & E. Vallance (Eds.) Conflicting conceptions of curriculum (pp. 162–175). Berkeley, CA: McCutchan Publishing Corp.
Schwartz, A.T. (1999). Creating a context for chemistry. Science & Education, 8(6), 605–618.
Schwartz, A.T., Bunce, D.M., Silberman, R.G., Stanitski, C.L., Straton, W.J., & Zipp, A.P. (1997). Chemistry in context: Applying chemistry to society (2nd ed.). Dubuque, IA: Wm. C. Brown.
Shiland, T.W. (1997). Quantum mechanics and conceptual change in high school chemistry textbooks. Journal of Research in Science Teaching, 34(5), 535–545.
Siegel, H. (1978). Kuhn and Schwab on science texts and the goals of science education. Educational Theory, 28, 302–309.
Skoog, G. (2005). The coverage of human evolution in high school biology textbooks in the 20th century and in current state science standards. Science & Education, 14(3–5), 395–422.
Smith, M.U. (2010). Current status of research in teaching and learning evolution: I. Philosophical/epistemological issues. Science & Education, 19, 523–538.
Tampakis, C., & Skordoulis, C. (2007). The history of teaching quantum mechanics in Greece. Science & Education, 16(3–5), 371–391.
Tarsitani, C., & Vicentini, M. (1996). Scientific mental representations of thermodynamcis. Science & Education, 5(1), 51–68.
Toon, E.R., & Ellis, G.L. (1978). Foundations of chemistry. Toronto: Holt, Rinehart & Winston.
Toon, E.R., Ellis, G.L., & Brodkin, J. (1968). Foundations of chemistry. New York: Holt, Rinehart & Winston.
Treagust, D.F., & Harrison, A.G. (2000). In search of explanatory frameworks: An analysis of Richard Feynman’s lecture ‘atoms in motion’. International Journal of Science Education, 22(11), 1157–1170.
Van Berkel, B., De Vos, W., & Verdonk, A.H., & Pilot, A. (2000). Normal science education and its dangers: The case of school chemistry. Science & Education, 9(1–2), 123–159.
Vaquero, J.M., & Santos, A. (2001). Heat and kinetic theory in 19th-century physics textbooks: The case of Spain. Science & Education, 10(3), 307–319.
Velentzas, A., Halkia, K., & Skordoulis, C. (2007). Thought experiments in the theory of relativity and in quantum mechanics: Their presence in textbooks and in popular science textbooks. Science & Education, 16(3–5), 353–370.
Wells, J. (2000). Icons of evolution, science or myth? Why much of what we teach about evolution is wrong. Washington, DC: Regnery.
Whitaker, R.J. (1999). Reflections on Catherine Milne’s “Philosophically correct stories? Examining the implications of heroic science stories for school science”. Journal of Research in Science Teaching, 36(10), 1148–1154.
Wilson, D. (1983). Rutherford: Simple genius. Cambridge, MA: MIT Press.
Zemplén, G.A. (2007). Conflicting agendas: Critical thinking versus science education in the international baccalaureate theory of knowledge course. Science & Education, 16, 167–196.
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Niaz, M. (2014). Science Textbooks: The Role of History and Philosophy of Science. In: Matthews, M. (eds) International Handbook of Research in History, Philosophy and Science Teaching. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-7654-8_44
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