Abstract
In the last decade, the term STEM has been increasingly picked up internationally and come to represent a solution to a range of issues. Within education, STEM is being translated as a curriculum organiser that has the possibility of engaging and retaining students and is interdisciplinary and skills focussed. This paper takes the STEM curriculum as its focus and investigates the influences that have resulted in the current interpretation of STEM as well as the epistemological questions, tensions and issues that this curriculum raises. The paper does this through a consideration of previous and current curriculum movements and debates and in doing so raises questions about the underlying assumptions, form and focus that STEM curriculum take before considering some possible future directions.
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References
Abbott, A. (2001). Chaos of disciplines. Chicago: University of Chicago Press.
Apple, M. (2004). Ideology and curriculum (3rd ed.). New York: Routledge.
Apple, M. W. (2013). Can education change society? New York: Routledge.
Ananiadou, K., & Claro, M. (2009). 21st century skills and competencies for new millennium learners in OECD countries (Vol. 41). OECD Education working papers. Paris: Organisation for economic cooperation and development (OECD).
Australian Curriculum and Assessment Authority. (n.d.) Australian curriculum. Retrieved from www.australiancurriculum.edu.au
Australian Industry Group. (2013). Lifting our science, technology engineering and mathematics (STEM) skills. Melbourne: Australian Industry Group.
Ball, S. J. (1994). Culture, crisis and morality: the struggle over the National Curriculum. In P. Atkinson, A. Davies, & S. Delamonte (Eds.), Discourse and reproduction: essays for Basil Bernstein (pp. 85–102). New York, NY: Hampton Press.
Ball, S. J. (2008). The education debate. Bristol: Policy Press.
Ball, S.J., Maguire, M., Braun, A., & Hoskins, K. (2011). Policy subjects and policy actors in schools: some necessary but insufficient analyses, discourse: studies in the cultural politics of education, 32(4), 611–624,
Barnes, J. (2015). Cross- curricular learning, 3–14, London: Sage.
Beane, J. (1997). Curriculum integration: designing the core of a democratic school. New York: Teachers College Press.
Becher, T. (1989). Academic tribes and territories: intellectual enquiry and the cultures of disciplines. Milton Keynes, England: Open University Press.
Beck, J. (2002). The sacred and the profane in recent struggles to promote official pedagogic identities. British Journal of Sociology of Education, 23(4), 617–626.
Bernstein, B. (1971). On the classification and framing of educational knowledge. In M. Young (Ed.), Knowledge and control: new directions for the sociology of education (pp. 47–69). London: Collier Macmillan.
Bernstein, B. (1990). Class, codes and control, volume IV: the structuring of pedagogic discourse. London: Routledge.
Bernstein, B. (1996). Pedagogy, symobolic control and identity. Theory, research and critique. London: Taylor and Francis.
Bernstein, B. (2000). Pedagogy, symbolic control and identity (Revised ed.). Lanham: Rowman and Littlefield.
Biesta, G. (2009). Good education in an age of measurement: On the need to reconnect with the question of purpose in education. Educational Assessment, Evaluation and Accountability (formerly: Journal of Personnel Evaluation in Education), 21(1), 33–46.
Blackmore, J. (1990). The text and context of vocationalism: issues in post-compulsory curriculum in Australia since 1970. Journal of Curriculum Studies, 22, 177–192.
Boix Mansilla, V., Miller, W. C., & Gardner, H. (2000). On disciplinary lenses and interdisciplinary work. Interdisciplinary curriculum: Challenges to implementation, 17–38.
Braun, A., Ball, S. J., & Maguire, M. (2011). Policy enactments in schools introduction: towards a toolbox for theory and research. Discourse: Studies in the Cultural Politics of Education, 32(4), 581–583.
Bybee, R. W. (2010). Advancing STEM education: A 2020 vision. Technology and Engineering Teacher, 70 (6), 30-35.
Cope, B., & Kalantzis, M. (2009). Ubiquitous learning. Urbana: University of Illinois Press.
Czerniak, C. M., & Johnson, C. C. (2014). Interdisciplinary science teaching. In N. G. Lederman & S. K. Abell (Eds.), Handbook of research on science education (Vol. II, pp. 395–411). New York: Routledge.
Department for Business, Innovation and Skills. (2015). 2010 to 2015 government policy: public understanding of science and engineering. UK Government. Retrieved from https://www.gov.uk/government/publications/2010-to-2015-government-policy-public-understanding-of-science-and-engineering
Department of Education. (2009). Report of the STEM Review. UK Government. Retrieved from https://www.education-ni.gov.uk/publications/report-stem-review
Department of Education and Training. (2016). STEM in the education state. Victorian Government. Retrieved from www.education.vic.gov.au/vicstem
Department of the Prime Minister and Cabinet (2015). National Innovation and Science Agenda. Canberra: Australian Government.
Dewey, J. (1956). The child and the curriculum and the school and society (combined Ed.) University of Chicago Press.
Doherty, C. (2015). The constraints of relevance on prevocational curriculum. Journal of Curriculum Studies, 47(5), 705–722.
Dowden, T. (2014). Challenging, integrated, negotiated and exploratory curriculum in the middle years of schooling: designing and implementing high quality curriculum integration, Australian Journal of Middle Schooling, 14(1), 16–27.
Drake, S. (1998). Creating integrated curriculum: proven ways to increase student learning. Thousand Oaks, CA: Corwin Press.
Edqvist, O. (2003). Layered science and science policies. Minerva: A Review of Science, Learning, and policy, 41(3), 207–221.
Education Council. (2015). National STEM school education strategy. Retrieved from www.educationcouncil.edu.au
Engineers Australia. (2017). Engineers make things happen. InThe need for an engineering pipeline strategy. Engineers Australia: ACT.
English, L. (2016). STEM education K-12: perspectives on integration. International Journal of STEM Education, 3(3), 1–8.
Fensham, P. (2009). Real world contexts in PISA science: implications for context-based science education. Journal of Research in Science Teaching, 46(8), 884–896.
Fensham, P. (2013). The science curriculum: the decline of expertise and the rise of bureaucratise. Journal of Curriculum Studies, 45(2), 152–168.
Fensham, P. (2016). The future curriculum for school science: what can be learnt from the past? Research in Science Education, 46, 165–185.
Fenwick, L. (2011). Curriculum reform and reproducing inequality in upper – secondary education. Journal of Curriculum Studies, 43, 697–716.
Feyerabend, P. (1993). Against method. London: Verso Books.
Freire, P. (1974). Pedagogy of the oppressed. (M. Ramos, Trans.). New York, NY: Seabury Press.
Frodeman, R. (2014). Sustainable knowledge: a theory of interdisciplinarity. New York: Palgrave Macmillan.
Gaff, J. G. and Wilson, R. C. (1971). Faculty cultures and interdisciplinary studies. The Journal of Higher Education, 186–201.
Gibbons, M., Limoges, C., Nowotny, H., Schwartzman, S., Scott, P., & Trow, M. (1994). The new production of knowledge the dynamics of science and research in contemporary societies. London: Sage.
Griffin, P., Care, E., & McGaw, B. (2012). The changing role of education and schools. In P. Griffin, E. Care and B McGaw (Eds.) Assessment and teaching of 21st century skills (pp. 1-15). Dordrecht: Springer.
Grossman, P., Wineburg, S., & Beers, S. (2000). Introduction: When theory meets practice in the world of school. In Eds. S. Wineburg and P. Grossman. Interdisciplinary Curriculum: Challenges to implementation (pp. 1–6). New York: Teachers College Press.
Honey, M., Pearson, G., & Schweingruber, H. (2014). STEM integration in K – 12 education: status, prospects, and an agenda for research. Washington: The National Academies Press.
Jacobs, J. A., & Frickel, S. (2009). Interdisciplinarity: a critical assessment. Annual Review of Sociology, 35, 43–65.
Karseth, B. (2006). Curriculum restructuring in Higher Education after the Bologna Process: a new pedagogic regime? Revista española de educación comparada, 12, 255–284.
Keating, J., & Klatt, M. (2013). The Australian concurrent federalism and its implications for the Gonski Review. Journal of Education Policy, 28(14), 411–426.
Kelley, T. R., & Knowles, J. G. (2016). A conceptual framework for integrated STEM education. International Journal of STEM Education, 3(11), 1–11.
Kennedy, T. J., & Odell, M. R. L. (2014). Engaging students in STEM education. Science Education International, 25(3), 246-258.
Klein, J. T. (1990). Interdisciplinarity: history, theory, and practice. Detroit: Wayne State University Press.
Klein, J. T. (1996). Crossing boundaries: knowledge, disciplinarities, and interdisciplinarities. Charlottesville: University Press of Virginia.
Klein, J. T. (2000). A conceptual vocabulary of interdisciplinary science. In P. Weingart & N. Stehr (Eds.), Practising Interdisciplinarity (pp. 3–24). Toronto: University of Toronto Press.
Lederman, N. G., & Niess, M. L. (1997). Editorial. School Science and Mathematics, 97(7), 341–344.
Leggett, B., & White, R. (2011). Waves of change: the critical role of assessment, reporting and accreditation in senior secondary curriculum reform in WA, 1975–2005. In L. Yates, C, Collins, & K. O’Connor (Eds.), Australia’s curriculum dilemmas: State cultures and the big issues (pp. 240–257). Carlton, VIC: Melbourne University Press.
Lingard, B. (2010). Policy borrowing, policy learning: testing times in Australian schooling. Critical Studies in Education, 51(2), 129–147.
Lyons, T., & Quinn, F. (2010). Choosing science: understanding the declines in senior high school science enrolments. Armidale, NSW: University of New England.
Madsen, D. (2018). Epistemological or political? Unpacking ambiguities in the field of interdisciplinary studies. Minerva, 56, 453–477.
Marginson, S., Tytler, R., Freeman, B., & Roberts, K. (2013). STEM: country comparisons: international comparisons of science, technology, engineering and mathematics (STEM) education. Final report. Melbourne, Vic: Australian Council of Learned Academies.
Maton, K., & Muller, J. (2007). A sociology for the transmission of knowledges. In F. Christie & J. R. Martin (Eds.), Language, knowledge & pedagogy. Functional linguistic and sociological perspectives (pp. 14–33). London: Continuum.
McDonald, C. V. (2016). STEM Education: a review of the contribution of the disciplines of science, technology, engineering and mathematics. Science Education International, 27(4), 530–569.
Millar, V. (2016). Interdisciplinary curriculum reform in the changing university. Teaching in Higher Education, 21(4), 471–483.
Millar, R., & Osborne, J. (Eds.). (1998). Beyond 2000: science education for the future. London: King’s College School of Education.
Ministry of Education (2009). The move to an integrated curriculum and inquiry learning. Retrieved from nzcurriculum.tki.org.nz/Curriculum-stories/Case-studies/Curriculum-implentation/Theme-six.
Moore, R., & Young, M. (2001). Knowledge and the curriculum in the sociology of education: towards a reconceptualisation. British Journal of Sociology of Education, 22(4), 445–461.
Morrison, J. (2006). TIES STEM education monograph series, attributes of STEM education. Baltimore, MD: TIES.
Muller, J. (2009). Forms of knowledge and curriculum coherence. Journal of Education and Work, 22(3), 205–226.
Muller, J. (2014). The future of knowledge and skills in science and technology higher education. Higher Education, 70(3), 409–416.
Muller, J., & Young, M. (2014). Disciplines, skills and the university. Higher Education, 67(2), 127–140.
Murgatroyd, S. (2010). ‘Wicked problem’ and the work of the school. European Journal of Education, 45(2), 259–279.
National Science and Technology Council, Committee on STEM Education. (2013). Federal Science, technology, engineering, and mathematics (STEM) education: 5-year strategic plan. Washington DC, United States of America: Executive Office of the President, US Government.
Newell, W. H. (1994). Designing interdisciplinary courses. New Directions for Teaching and Learning, 1994(58), 35–51.
Nowotny, H., Scott, P., & Gibbons, M. (2001). Re-thinking science: knowledge and the public in an age of uncertainty. Cambridge: Polity Press.
Nowotny, H., Scott, P., & Gibbons, M. (2003). Introduction: ‘Mode 2’ revisited: The new production of knowledge. Minerva: A Review of Science, Learning, and Policy, 41(3), 179–194.
Office of the Chief Scientist. (2012). Health of Australian science. Canberra, ACT: Australian Government. Retrieved from http:www.chiefscientist.gov.au/wp-content/uploads/HASRReportWebUpdat200912.pdf
Office of the Chief Scientist. (2014). Science, technology, engineering and mathematics: Australia’s future. Canberra, ACT: Australian Government.
OECD. (2005) Definition and selection of competencies executive summary. Paris: Organisation for Economic Cooperation and Development (OECD). Retrieved from http://www.oecd.org/pisa/35070367.pdf
Osborne, J. (2006). Towards a science education for all: The role of ideas, evidence and argument. ACER.
Petrie, H.G. (1992). Interdisciplinary Education: are we faced with insurmountable opportunities? In G. Grant (Ed.) Review of Research in Education, vol. 18, pp. 299–333. Washington D.C.: American Educational Research Association.
PWC. (2015). Future-proofing Australia’s workforce by growing skills in science, technology, engineering and maths (STEM). Melbourne: PWC.
Reid, A., & Price, D. (Eds.). (2018). The Australian curriculum: promises, problems and possibilities. ACT: Australian Curriculum Studies Association.
Rizvi, F., & Lingard, B. (2010). Globalizing education policy. London: Routledge.
Rizvi, F. (2011). Theorising student mobility in an era of globalisation. Teachers and Teaching, 17(6), 693–701.
Rudolph, S., Sriprakash, A., & Gerrard, J. (2018). Knowledge and racial violence: the shine and shadow of ‘powerful knowledge’. Ethics and Education. https://doi.org/10.1080/17449642.2018.1428719.
Schwab, J. J. (1962). The teaching of science as enquiry. Cambridge, MA: Harvard University Press.
Sellar, S., & Lingard, B. (2013). The OECD and global governance in education. Journal of Education Policy, 28(5), 710–725.
Sharma, B. R. (2004). Strategies of non-formal education. New Delhi: Sarup & Sons.
Singh, P., Thomas, S., & Harris, J. (2013). Recontextualising policy discourses: a Bernsteinian perspective on policy interpretation, translation, enactment. Journal of Education Policy, 28(4), 465–480.
Sokal, R. R. (1974). Classification: purposes, principles, progress, prospects. Science, 185(4157), 1115–1123.
Stichweh, R. (1992). The sociology of scientific disciplines: on the genesis and stability of the disciplinary structure of modern science. Science in Context, 5, 3–15.
Teese, R., & Polesel, J. (2003). Undemocratic schooling: equity and quality in mass secondary education in Australia. Carlton: Melbourne University Press.
The Royal Society Science Policy Centre. (June, 2014). Vision for science and mathematics education. London: The Royal Society.
Tytler, R., Osborne, J., Williams, G., Tytler, K., & Cripps Clark, J. (2008). Opening up pathways: engagement in STEM across the primary-secondary school transition. Canberra: Australian Department of Education, Employment and Workplace Relations.
Tsui, L. (1999). Courses and instruction affecting critical thinking. Research in Higher Education, 40(2), 185–200.
Van Driel, J. H., Verloop, N., & De Vos, W. (1998). Developing science teachers’ pedagogical content knowledge. Journal of Research in Science Teaching, 35(6), 673–695.
Venville, G. J., Wallace, J., Rennie, L. J., & Malone. (2002). Curriculum integration: eroding the high ground of science as a school subject? Studies in Science Education, 37(1), 43–83.
Wahlstrom, N. (2018). Where is ‘the political’ in curriculum research. Journal of Curriculum Studies, 50(6), 711–723.
Weingart, P. (1997). From ‘finalization’ to ‘mode 2’: old wine in new bottles? Social Science Information, 36(4), 591–613.
Weingart, P., & Stehr, N. (Eds.). (2000). Practising interdisciplinarity. Toronto: University of Toronto Press.
Whitty, G. (2010). Revisiting school knowledge: some sociological perspectives on new school curricula. European Journal of Education, 45(1), 28–45.
Winch, C. (2013). Curriculum design and epistemic ascent. Journal of Philosophy of Education, 47(1), 128–146.
Wineburg, S., & Grossman, P. (2000). Interdisciplinary curriculum: challenges to implementation. New York: Teachers College Press.
Wood, T., Cobb, P., & Yackel, E. (2012). Reflections on learning and teaching mathematics in elementary school. In L. P. Steffe & J. Gale (Eds.), Constructivism in education (pp. 419–440). New York: Routledge.
Wong, V., Dillon, J., & King, H. (2016). STEM in England: meanings and motivations in the policy arena. International Journal of Science Education, 38(15), 2346–2366.
Wong, V., & Dillon, J. (2019). ‘Voodoo maths’, asymmetric dependency and maths blame: why collaboration between school science and mathematics teachers is so rare. International Journal of Science Education, 41(6), 782–802.
Wrigley, T. (2018). ‘Knowledge’, curriculum and social justice. The Curriculum Journal, 29(1), 4–24.
Yates, L., Collins, C. W., & O'Connor, K. (2011). Australia's curriculum dilemmas: state cultures and the big issues. Carlton: Melbourne University Publishing.
Yates, L., & Grumet, M. (2011). Curriculum in today’s world: configuring knowledge identities, work and politics. In L. Yates & M. Grumet (Eds.), World yearbook of education 2011: Configuring knowledge, identities, work and politics (pp. 3–14). London: Routledge.
Yates, L., Woelert, P., Millar, V., & O’Connor, K. (2016). Knowledge at the Crossroads?: Physics and History in the Changing World of Schools and Universities. Singapore: Springer
Young, M. (Ed.). (1971). Knowledge and control: new directions for the sociology of education. London: Collier-Macmillan.
Young, M. (2008). Bringing knowledge back in: from social constructivism to social realism in the sociology of education. London: Routledge.
Young, M. (2010). Alternative educational futures for a knowledge society. European Education Research Journal, 9(1), 1–12.
Zipin, L. (2013). Starting from pedagogical zero in ‘developing’ contexts? Let’s re-imagine!: a response to Hugo and Wedekind. Southern African Review of Education, 19(1), 158–166.
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Millar, V. Trends, Issues and Possibilities for an Interdisciplinary STEM Curriculum. Sci & Educ 29, 929–948 (2020). https://doi.org/10.1007/s11191-020-00144-4
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DOI: https://doi.org/10.1007/s11191-020-00144-4