Abstract
There is no consensus in the science education research community on the meanings and representations of western science and indigenous knowledge or the relationships between them. How students interpret these relationships and their perceptions of any connections has rarely been studied. This study reports student perceptions of the meaning and relationship between scientific and cultural knowledge. Personal meaning maps adapted for small groups were conducted in seven culturally diverse schools, school years 7–9 (with students aged 12–15 years) (n = 190), with six schools in Western Australia and one school in Malawi, Africa. Of the six Australian school groups, two comprised Australian Aboriginal students in an after-school homework programme and the other four schools had a multicultural mix of students. Students in this study identified connections between scientific and cultural knowledge and constructed connections from particular thematic areas—mainly factual content knowledge as opposed to ideas related to values, attitudes, beliefs and identity. Australian Aboriginal students made fewer connections between the two knowledge domains than Malawian students whose previous science teacher had made explicit connections in her science class. Examples from Aboriginal culture were the most dominant illustrations of cultural knowledge in Australian schools, even in school groups with students from other cultures. In light of our findings, we discuss the construction of common ground between scientific knowledge and cultural knowledge and the role of teachers as cultural brokers and travel agents. We conclude with recommendations on creating learning environments that embrace different cultural knowledges and that promote explicit and enquiring discussions of values, attitudes, beliefs and identity associated with both knowledge domains.
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References
Aikenhead, G. (1996). Science education: border crossing into the subculture of science. Studies in Science Education, 27(1), 1–52.
Aikenhead, G. (1997). Toward a first nations cross-cultural science and technology curriculum. Science Education, 81(2), 217–238.
Aikenhead, G. (2001). Integrating Western and Aboriginal sciences: cross-cultural science teaching. Research in Science Education, 31(3), 337–355.
Aikenhead, G., & Jegede, O. (1999). Cross-cultural science education: a cognitive explanation of a cultural phenomenon. Journal of Research in Science Teaching, 36(3), 269–287.
Aikenhead, G., & Ogawa, M. (2007). Indigenous knowledge and science revisited. Cultural Studies of Science Education, 2(3), 539–620.
Aikenhead, G., & Ryan, A. (1992). The development of a new instrument: Views on Science-Technology-Society (VOSTS). Science Education, 76(5), 477–491.
Austin, J., & Hickey, A. (2011). Incorporating indigenous knowledge into the curriculum: responses of science teacher educators. The International Journal of Science in Society, 2(4), 139–152.
Australian Bureau of Statistics. (2008). National Aboriginal and Torres Strait Islander Social Survey. Retrieved July 20, 2012, from http://www.abs.gov.au/ausstats/abs@.nsf/Latestproducts/4714.0Main%20Features22008?opendocument&tabname=Summary&prodno=4714.0&issue=2008&num=&view=.
Australian Bureau of Statistics. (2012). Reflecting a nation: stories from the 2011 Census, 2012–2013. Retrieved 28 September, 2012, from http://www.abs.gov.au/ausstats/abs@.nsf/Lookup/2071.0main+features902012-2013.
Australian Curriculum Assessment and Reporting Authority (2011) The shape of the Australian curriculum: languages. Retrieved from http://www.acara.edu.au/verve/_resources/Languages_-_Shape_of_the_Australian_Curriculum.pdf.
Australian Curriculum Assessment and Reporting Authority. (2012a). General capabilities in the Australian curriculum. Sydney, Australia.
Australian Curriculum Assessment and Reporting Authority. (2012). General capabilities in the Australian Curriculum. Intercultural Understanding, Sydney, Australia
Baker, J. O. (2013). Acceptance of evolution and support for teaching creationism in public schools: the conditional impact of educational attainment. Journal for the Scientific Study of Religion, 52(1), 216–228. doi:10.1111/jssr.12007.
Banks, J. A. (1991). Teaching strategies for ethnic studies. Needham Heights: Allyn and Bacon Inc.
Banks, J. A., & Banks, C. A. M. (2009). Multicultural education: issues and perspectives. Hoboken: Wiley.
Baynes, R., & Austin, J. (2012). Indigenous knowledge in the Australian national curriculum for science: from conjecture to classroom practice. Paper presented at the 5th Biennial International Indigenous Development Research Conference, Auckland: New Zealand.
Berkes, F., Colding, J., & Folke, C. (2000). Rediscovery of traditional ecological knowledge as adaptive management. Ecological Applications, 10(5), 1251–1262.
Brandt, C. (2007). Epistemology and temporal/spatial orders in science education: A response to Aikenhead & Ogawa's: Indigenous knowledge and science revisited. Cultural Studies of Science Education, 2(3), 539–620.
Brunton, R. (1998). Betraying the victims: the ‘stolen generation’ report. IPA Backgrounder, 10(1), 1–24.
Calabrese Barton, A., & Tan, E. (2009). Funds of knowledge and discourses and hybrid space. Journal of Research in Science Teaching, 46(1), 50–73.
Chimombo, J., Kunje, D., Chimuzu, T., & Mchikoma, C. (2005). The SACMEQ II Project in Malawi: a study of the conditions of schooling and the quality of education. Retrieved from http://www.sacmeq.org/education-malawi.htm.
Chiu, M.-H., & Duit, R. (2011). Globalization: science education from an international perspective. Journal of Research in Science Teaching, 48(6), 553–566.
Cobern, W. W. (1996). Worldview theory and conceptual change in science education. Science Education, 80(5), 579–610.
Cobern, W. W., & Loving, C. C (2004). Defining ‘science’ in a multicultural world. Reconsidering science learning (pp. 50-67). New York: Routledge Routledge.
Creswell, J. W. (2008). Research design: qualitative, quantitative, and mixed methods approaches. Thousand Oaks, California: Sage Publications, Inc.
Davis, K. S. (2003). “Change is hard”: what science teachers are telling us about reform and teacher learning of innovative practices. Science Education, 87(1), 3–30.
De Bortoli, L. J., & Thomson, S. (2010). Contextual factors that influence the achievement of Australia’s indigenous students: results from PISA 2000-2006. Retrieved from www.acer.edu.au/documents/pisa-indigenous-contextual-factors.pdf.
Department of Education Western Australia. (2012). Aboriginal education glossary. Retrieved 12th March, 2012, from http://www.det.wa.edu.au/aboriginaleducation/detcms/navigation/glossary.jsp.
Dzama, E., Holtman, L., Kolstø, S. D., & Mikalsen, Ø. (2008). Practice-related underachievement in science education: the case of Malawi. In L. Holtman, C. Julie, Ø. Mikalsen, D. Mtetwa, & M. Ogunniyi (Eds.), Some developments in research in science and mathematics in Sub-Saharan Africa: access, relevance, learning, curriculum research (p. 207–224). Somerset West: African Minds.
Eppler, M. J. (2006). A comparison between concept maps, mind maps, conceptual diagrams, and visual metaphors as complementary tools for knowledge construction and sharing. Information Visualization, 5(3), 202–210.
Falk, J., & Storksdieck, M. (2005). Using the contextual model of learning to understand visitor learning from a science center exhibition. Science Education, 89(5), 744–778.
Fensham, P. J. (2008). Science education policy-making: eleven emerging issues. Paris: UNESCO.
Field, A. (2009). Discovering statistics using SPSS. Thousand Oaks, California: Sage Publications Inc.
Gay, G. (2003). The importance of multicultural education. Educational Leadership, 61(4), 30–35.
Gee, J. P. (1996). Social linguistics and literacies: ideology in discourses (2nd ed.). London: Farmer.
Given, L. M. (2008). The SAGE encyclopedia of qualitative research methods (Vol. 2). Thousand Oaks, California: Sage Publications, Inc.
Glasson, G. E., Mhango, N., Phiri, A., & Lanier, M. (2010). Sustainability science education in Africa: negotiating indigenous ways of living with nature in the third space. International Journal of Science Education, 32(1), 125–141.
Gondwe, M., & Longnecker, N. (2011). A framework for engaging Indigenous students with science through storytelling. Paper presented at the Australasian Science and Education Research Association, Australia: Adelaide.
Good, R. (1995). Comments on multicultural science education. Science Education, 79(3), 335–336.
Guerra-Ramos, M. T., Ryder, J., & Leach, J. (2010). Ideas about the nature of science in pedagogically relevant contexts: insights from a situated perspective of primary teachers’ knowledge. Science Education, 94(2), 282–307.
Hackling, M., Peers, S., & Prain, V. (2007). Primary connections: reforming science teaching in Australian primary schools. Teaching Science, 55(3), 12–17.
Hidalgo, N. M. (1993). Multicultural teacher introspection. In T. Perry & J. W. Fraser (Eds.), Freedom’s plow: Teaching in the multicultural classroom (pp. 99–106). New York: Routledge.
Hodson, D. (1993). In search of a rationale for multicultural science education. Science Education, 77(6), 685–711. doi:10.1002/sce.3730770611.
Hodson, D. (2003). Time for action: science education for an alternative future. International Journal of Science Education, 25(6), 645–670.
Horstman, M., & Wightman, G. (2001). Karparti ecology: recognition of Aboriginal ecological knowledge and its application to management in north-western Australia. Ecological Management & Restoration, 2(2), 99–109.
Hunting, H. (2000). Using traditional ecological knowledge in science methods and applications. Ecological Application, 10(5), 12270–11274.
Jegede, O. (1995). Collateral learning and the eco-cultural paradigm in science and mathematics education in Africa. Studies in Science Education, 25(1), 97–137.
Kozoll, R. H., & Osborne, M. D. (2004). Finding meaning in science: lifeworld, identity, and self. Science Education, 88(2), 157–181.
Krippendorff, K. (2004). Content analysis: an introduction to its methodology. Thousand Oaks, California: Sage Publications, Inc.
Ladson-Billings, G. (1995). But that’s just good teaching! The case for culturally relevant pedagogy. Theory Into Practice, 34(3), 159–165.
Le Grange, L. (2007). Integrating western and indigenous knowledge systems: the basis for effective science education in South Africa? International Review of Education, 53(5), 577–591.
Lederman, N. G. (2006). Students’ and teachers’ conceptions of the nature of science: a review of the research. Journal of Research in Science Teaching, 29(4), 331–359.
Lederman, N. G., Abd-El-Khalick, F., Bell, R. L., & Schwartz, R. S. (2002). Views of nature of science questionnaire: toward valid and meaningful assessment of learners’ conceptions of nature of science. Journal of Research in Science Teaching, 39(6), 497–521.
Lee, C. D., Spencer, M. B., & Harpalani, V. (2003). “Every shut eye ain’t sleep”: studying how people live culturally. Educational Researcher, 32(5), 6–13.
Lee, H., Yen, C., & Aikenhead, G. (2012). Indigenous elementary students’ science instruction in Taiwan: indigenous knowledge and Western science. Research in Science Education, 42(6), 1183–1199. doi:10.1007/s11165-011-9240-7.
Lombard, M., Snyder-Duch, J., & Bracken, C. C. (2004). Practical resources for assessing and reporting intercoder reliability in content analysis research projects. Retrieved from http://www.slis.indiana.edu/faculty/hrosenba/www/Research/methods/lombard_reliability.pdf
Martin, K., & Mirraboopa, B. (2003). Ways of knowing, being and doing: a theoretical framework and methods for indigenous and indigenist research. Journal of Australian Studies, 27(76), 203–214.
Maxwell, J. A. (2004). Qualitative research design: an interactive approach. Newbury Park, CA: Sage Publications, Inc..
McConney, A., Oliver, M., Woods-McConney, A., & Schibeci, R. (2010). Bridging the gap? A comparative, retrospective analysis of science literacy and interest in science for Indigenous and non-Indigenous Australian students. International Journal of Science Education, 33(14), 2017–2035.
McInerney, V. (2003). Multiculturalism in today’s schools: have teachers’ attitudes changed over two decades? Paper presented at the SELF Research Centre at the Annual Meeting of the Australian Association for the Research in Education , Auckland, New Zealand.
McKinley, E. (1996). Towards an indigenous science curriculum. Research in Science Education, 26(2), 155–167.
McKinley, E., & Stewart, G. (2009). Falling into place. Indigenous science education research in the Pacific. In R. S (Ed.), The world of science education: Handbook of research in Australasia (pp. 49-66). Rotterdam: Sense Publishers.
McNaught, C., & Lam, P. (2010). Using Wordle as a supplementary research tool. The Qualitative Report, 15(3), 630–643.
Mellor, S., & Cooringan, M. (2004). The case for change: A review of contemporary research of Indigenous education outcomes. Retrieved from http://research.acer.edu.au/cgi/viewcontent.cgi?article=1006&context=aer
Michie, M. (2002). Why Indigenous science should be included in the school science curriculum. Australian Science Teachers, 48(2), 36–40.
Ministerial Council on Education, Employment, Training, and Youth Affairs. (2008). Melbourne declaration on educational goals for young Australians. Retrieved from http://www.mceecdya.edu.au/verve/_resources/National_Declaration_on_the_Educational_Goals_for_Young_Australians.pdf.
Moje, E., Ciechanowski, K., Kramer, K., Ellis, L., Carrillo, R., & Collazo, T. (2004). Working toward third space in content area literacy: an examination of everyday funds of knowledge and discourse. Reading Research Quarterly, 39(1), 38–70.
Munro, H. (2007). Use of appropriate language when working with Aboriginal communities in NSW. Retrieved from http://www.community.nsw.gov.au/docswr/_assets/main/documents/researchnotes_aboriginal_language.pdf
National Health and Medical Research Council. (2003). Values and ethics—guidelines for ethical conduct in Aboriginal and Torres Strait Islander health research. Retrieved from http://www.nhmrc.gov.au/_files_nhmrc/publications/attachments/e52.pdf.
Ninnes, P. (2000). Representations of indigenous knowledges in secondary school science textbooks in Australia and Canada. International Journal of Science Education, 22(6), 603–617.
Ogawa, M. (1995). Science education in a multiscience perspective. Science Education, 79(5), 583–593.
Ogunniyi, M. B. (2007). Teachers’ stances and practical arguments regarding a science-indigenous knowledge curriculum: Part 2. International Journal of Science Education, 29(10), 1189–1207.
Pallant, J. (2010). SPSS survival manual: a step by step guide to data analysis using SPSS (4th ed.). Maidenhead McGraw-Hill International (UK) Ltd.
Parsons, E. C., & Carlone, H. B. (2013). Culture and science education in the 21st century: extending and making the cultural box more inclusive. Journal of Research in Science Teaching, 50(1), 1–11.
Phiri, A. D. (2008). Exploring the integration of Indigenous science in the primary school science curriculum in Malawi. Unpublished Doctor of Philosophy dissertation, Virginia Polytechnic Institute and State University.
Phua, V. (2003). Convenience sample. In A. E. Bryman, T. F. Liao, & M. Lewis-Beck (Eds.), The Sage encyclopedia of social science research methods (Vol. 1, p. 198). Thousand Oaks, California: Sage Publications, Inc.
Raymond, C. M., Fazey, I., Reed, M. S., Stringer, L. C., Robinson, G. M., & Evely, A. C. (2010). Integrating local and scientific knowledge for environmental management. Journal of Environmental Management, 91(8), 1766–1777.
Reid, C. (2001). Magpie babies: urban Aboriginal students, identity and inequality in education. In A. Ward & R. Bouvier (Eds.), Resting lightly on Mother Earth: The Aboriginal experience in urban educational settings. Calgary, Alberta: Detselig Enterprises.
Rosenberg, S., Hammer, D., & Phelan, J. (2006). Multiple epistemological coherences in an eighth-grade discussion of the rock cycle. The Journal of the Learning Sciences, 15(2), 261–292.
Rothstein-Fisch, C., Greenfield, P., & Trumbull, E. (2003). Bridging cultures with classroom strategies. Bridging Cultures with classroom strategies. New Jersey: Lawrence Erlbaum Associates.
Rubba, P. A., & Harkness, W. J. (1996). A new scoring procedure for the views on science-technology-society instrument. International Journal of Science Education, 18(4), 387–400.
Russell-Smith, J., Lucas, D., Gapindi, M., Gunbunuka, B., Kapirigi, N., Namingum, G., et al. (1997). Aboriginal resource utilization and fire management practice in western Arnhem Land, monsoonal northern Australia: notes for prehistory, lessons for the future. Human Ecology, 25(2), 159–195.
Saldana, J. (2009). The coding manual for qualitive researchers. London: Sage Publications, Inc.
Schreiner, C., & Sjøberg, S. (2007). Science education and youth’s identity construction—two incomptabile projects? In D. Corrigan, J. Dillon, & R. Gunstone (Eds.), The re-emergence of values in science education (p. 231). Rotterdam: Sense Publishers.
Seiler, G. (2013). New metaphors about culture: implications for research in science teacher preparation. Journal of Research in Science Teaching, 50(1), 104–121.
Shumba, O. (1999). Relationship between secondary science teachers’ orientation to traditional culture and beliefs concerning science instructional ideology. Journal of Research in Science Teaching, 36(3), 333–355.
Snively, G., & Corsiglia, J. (2001). Discovering indigenous science: implications for science education. Science Education, 85(1), 6–34.
Stephens, S. (2003). Handbook for culturally responsive science curriculum. Fairbanks, AK: Alaska Native Knowledge Network.
Stocklmayer, S. M., & Gilbert, J. (2003). Informal chemical education. Chemical Education: Towards Research-based Practice, 17, 143–164.
Stocklmayer, S. M., Rennie, L. J., & Gilbert, J. K. (2010). The roles of the formal and informal sectors in the provision of effective science education. Studies in Science Education, 46(1), 1–44.
Swetnam, L. (2003). Lessons on multicultural education from Australia and the United States. The Clearing House, 76(4), 208–211.
Taber, K. S., Billingsley, B., Riga, F., & Newdick, H. (2011). Secondary students’ responses to perceptions of the relationship between science and religion: stances identified from an interview study. Science Education, 95(6), 1000–1025.
Tan, E., & Calabrese Barton, A. (2010). Transforming science learning and student participation in sixth grade science class: a case study of a low-income, urban, racial minority classroom. Equity and Excellence in Education, 43, 38–55.
Thomson, S., & De Bortoli, L. (2008). Exploring scientific literacy: how Australia measures up. The PISA 2006 survey of students’ scientific, reading and mathematical literacy skills. Camberwell Victoria, Australia: ACER Press.
Tsurusaki, B. K., Calabrese Barton, A., Tan, E., Koch, P., & Contento, I. (2013). Using transformative boundary objects to create critical engagement in science: a case study. Science Education, 97(1), 1–31.
Woods-McConney, A., Oliver, M., McConney, A., Maor, D., & Schibeci, R. (2011). Science engagement and literacy: A retrospective analysis for Indigenous and non-Indigenous students in Aotearoa New Zealand and Australia. Research in Science Education, 1-20. doi: 10.1007/s11165-011-9265-y
Yin, R. K. (2003). Case study research: design and methods (vol. 5). Thousand Oaks, California: Sage Publications, Inc.
Acknowledgments
This work was supported by an Australian Research Council Linkage grant (LP100100640). We thank our co-investigators of the project, staff at the Gravity Discovery Centre and Graham Polly Farmer Foundation (partners in the research grant) for facilitating group participation and Fred Deshon for introducing us to School Green. We thank the principals and teachers who provided access to their classes and students who participated in this study.
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Gondwe, M., Longnecker, N. Scientific and Cultural Knowledge in Intercultural Science Education: Student Perceptions of Common Ground. Res Sci Educ 45, 117–147 (2015). https://doi.org/10.1007/s11165-014-9416-z
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DOI: https://doi.org/10.1007/s11165-014-9416-z