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Research in Science Education

, Volume 49, Issue 2, pp 613–634 | Cite as

The Development of a Scientific Motive: How Preschool Science and Home Play Reciprocally Contribute to Science Learning

  • Judith GomesEmail author
  • Marilyn Fleer
Article

Abstract

There are a growing number of studies that have examined science learning for preschool children. Some research has looked into children’s home experiences and some has focused on transition, practices, routines, and traditions in preschool contexts. However, little attention has been directed to the relationship between children’s learning experiences at preschool and at home, and how this relationship can assist in the development of science concepts relevant to everyday life. In drawing upon Hedegaard’s (Learning and child development, 2002) cultural-historical conception of motives and Vygotsky’s (The collected works of L.S. Vygotsky: problems of general psychology, 1987) theory of everyday and scientific concept formation, the study reported in this paper examines one child, Jimmy (4.2 years), and his learning experiences at home and at preschool. Data gathering featured the video recording of 4 weeks of Jimmy’s learning in play at home and at preschool (38.5 h), parent questionnaire and interviews, and researcher and family gathered video observations of home play with his parents (3.5 h). Findings show how a scientific motive develops through playful everyday learning moments at home and at preschool when scientific play narratives and resources are aligned. The study contributes to a more nuanced understanding of the science learning of young children and a conception of pedagogy that takes into account the reciprocity of home and school contexts for learning science.

Keywords

Play Concept formation Science Cultural-historical theory Early childhood 

Notes

Acknowledgements

This paper was presented at the 2014 ASERA conference, Melbourne. Special thanks to the research participants of this study. A very special thank to the cultural-historical research community at Monash University for the constructive feedback in the presentation of this manuscript. The first author is a PhD student at Faculty of Education, Monash University and recipient of the Australian Postgraduate Award (APA) and the Monash Graduate Scholarship (MGS). The first author won the ASG (Australian Scholarships Group) 2016 travel grant for nominating this paper. Her study was situated in the broader context of an Australian Research Council Discovery Grant scheme (grant number DP130101438) project lead by the second author. The participants were drawn separately from the broader project for the purpose of researching the problem addressed in this paper. A special acknowledgement to field leader Sue March for overall project management. Research assistance was provided by Feiyan Chen, Yijun Hao, Hasnat Jahan, Mahbub Sarkar, Shuhuan Pang, Shukla Sikder, and Pui Ling Wong. Support from Madeleine Holland and Rowan Fleer-Stout with data organisation is appreciated for the broader project. Special acknowledgment of the staff and families involved in the study is made, as without their involvement new understandings would not be possible.

References

  1. Appleton, K. (1985). Children’s ideas about temperature. Research in Science Education, 15, 122–126.CrossRefGoogle Scholar
  2. Chaiklin, S. (2012). A conceptual perspective for investigating motive in cultural-historical theory. In M. Hedegaard, A. Edwards, & M. Fleer (Eds.), Motives in children’s development: cultural-historical approaches (pp. 209–224). Cambridge: Cambridge University Press.Google Scholar
  3. Department of Education Employment and Workplace [DEEWR]. (2009). Being, belonging and becoming. Australian Capital Territory.Google Scholar
  4. Driver, R. (1983). The pupil as scientist? Buckingham: Open University Press.Google Scholar
  5. Duit, R. (2009). Bibliography-STCSE. Students’ and teachers’ conceptions and science education. Retrieved 7–07-10, from http://www.ipn.uni-kiel.de/aktuell/stcse/stcse.html
  6. El’konin, D. B. (2005). The subject of our research: the developed form of play. Journal of Russian and East European Psychology, 43(1), 22–48.CrossRefGoogle Scholar
  7. Fleer, M. (1991). Socially constructed learning in early childhood science education. Research in Science Education, 21, 96–103.CrossRefGoogle Scholar
  8. Fleer, M. (1995). The importance of conceptually focused teacher-child interaction in early childhood science teaching. International Journal of Science Education, 17(3), 325–342.CrossRefGoogle Scholar
  9. Fleer, M. (1996). Fusing the boundaries between home and child care to support childrenʼs scientific learning. Research in Science Education, 26(2), 143–154.CrossRefGoogle Scholar
  10. Fleer, M. (1999). Childrenʼs alternative views: alternative to what? International Journal of Early Years Education, 21(2), 119–136.Google Scholar
  11. Fleer, M. (2007). Concept formation: a cultural-historical perspective. In M. Fleer (Ed.), Young children: thinking about the scientific world (pp. 11–14). Australian Capital Territory: Early Chhildhood Australia INC..Google Scholar
  12. Fleer, M. (2009a). A cultural-historical perspective on play: play as a leading activity across cultural communities. In Pramling-Samuelsson & M. Fleer (Eds.), Play and learning in early childhood settings: international perspectives (pp. 1–18). Dordrecht: Springer.Google Scholar
  13. Fleer, M. (2009b). Understanding the dialectical relations between everyday concepts and scientific concepts within play-based programs. Research in Science Education, 39, 281–306. doi: 10.1007/s11165-008-9085-x.CrossRefGoogle Scholar
  14. Fleer, M. (2010). Early learning and development: cultural-historical concepts in play. Port Melbourne: Cambridge University Press.CrossRefGoogle Scholar
  15. Fleer, M. (2011). “Conceptual play”: foregrounding imagination and cognition during concept formation in early years education. Contemporary Issues in Early Childhood., 12(3), 224–240.CrossRefGoogle Scholar
  16. Fleer, M. (2012). The development of motives in children’s play. In M. Hedegaard, A. Edwards, & M. Fleer (Eds.), Motives in children’s development: cultural-historical approaches (pp. 79–96). New York: Cambridge University Press.Google Scholar
  17. Fleer, M., & Beasley, W. (1991). A study of conceptual development in early childhood. [journal article]. Research in Science Education, 21(1), 104–112. doi: 10.1007/bf02360463.CrossRefGoogle Scholar
  18. Fleer, M., & Pramling, N. (2015). A cultural-historical study of children learning science: foregrounding affective imagination in play-based setting. Dordrecht: Springer.CrossRefGoogle Scholar
  19. Fleer, M., & Robbins, J. (2003). “Hit and run research” with “hit and miss” results in early childhood science education. Research in Science Eduation, 33, 405–431.CrossRefGoogle Scholar
  20. Fleer, M., Gomes, J. J., & March, S. (2014). Science learning affordances in preschool environments. Australasian Journal of Early Childhood, 39(1), 38–48.CrossRefGoogle Scholar
  21. Galili, I. (1995). Interpretation of students’ understanding of the concept of weightlessness. Research in Science Education, 25(1), 51–74. doi: 10.1007/bf02356460.CrossRefGoogle Scholar
  22. Gunstone, R. F., & White, R. T. (2008). The conceptual change approach and the teaching of science. In S. Vosniadou (Ed.), International handbook of research on conceptual change. New York: Routledge.Google Scholar
  23. Hargraves, V. (2014). Children’s theorising about their world: exploring the practitioner’s role. Australian Journal of Early Childhood, 39(1), 30–37.CrossRefGoogle Scholar
  24. Hedegaard, M. (2002). Learning and child development. Aarhus: Aarhus University Press.Google Scholar
  25. Hedegaard, M. (2012). The dynamic aspects in children’s learning and development. In M. Hedegaard, A. Edwards, & M. Fleer (Eds.), Motives in children’s development: cultural-historical approaches (pp. 9–27). New York: Cambridge University Press.Google Scholar
  26. Hedegaard, M. & Chaiklin, S. (2005). Radical-Local Teaching and Learning. A Cultural-Historical Approach. Aarhus, Denmark: Aarhus University Press.Google Scholar
  27. Hedegaard, M. & Fleer, M. (2008). Studying children: A cultural-historical approach. Berkshire: Open University Press.Google Scholar
  28. Merriam, S. B. (2009). Qualitative research: a gude to research and implementation. San Francisco: Jossey-Bass.Google Scholar
  29. Milner, A. R., Templin, M. A., & Czerniak, C. M. (2011). Elementary science students’ motivation and learning strategy use: constructivist classroom. Journal of Science Teacher Education, 22(2), 151–170.CrossRefGoogle Scholar
  30. O’Loughlin, M. (1992). Rethinking science education: beyond Piagetian constructivism toward a sociocultural model of teaching and learning. Journal of Research in Science Teaching, 29(8), 791–820.CrossRefGoogle Scholar
  31. Osborne, R., & Freyberg, P. (1985). Learning in science. Auckland: Heinemann Education.Google Scholar
  32. Silfverberg, H. (2006). The disappearence of light: explanations given by the primary school pupils. NorDiNA-Nordic Studies in Science Education, 5, 43–53.Google Scholar
  33. Siry, C., & Kremer, I. (2011). Children explain the rainbow: using young childrenʼs ideas to guide science curricula. Journal of Science Education and Technology, 20, 643–655. doi: 10.1007/s10956-011-9320-5.CrossRefGoogle Scholar
  34. Tsai, C. H., Chen, H. Y., Chou, C. Y., & Lain, K. D. (2007). Current as the key concept of Taiwanese students’ understandings of electric circuits. International Journal of Science Education, 29(4), 483–496. doi: 10.1080/09500690601073327.CrossRefGoogle Scholar
  35. Tytler, R., & Osborne, J. (2012). Student attitudes and aspirations towards science. In B. J. Fraser, K. Tobin, & C. J. McRobbie (Eds.), Second international handbook of science education (pp. 597–625). New York: Springer.Google Scholar
  36. Vygotsky, L. S. (1966). Play and its role in the mental development of the child. Voprosy psikhologi, 12(6), 62–78.Google Scholar
  37. Vygotsky, L. S. (1987). The development of scientific concepts in childhood (N. Minick, Trans.) In R. W. Rieber & A. S. Carton (Eds.), The collected works of L.S. Vygotsky: problems of general psychology (pp. 167–242). New York: Plenum Press.Google Scholar
  38. Watters, J. J., & Ginns, I. S. (2000). Developing motivation to teach elementary science: effect of collaborative and authentic learning practices in preservice education. Journal of Science Teacher Education, 11(4), 301–321.CrossRefGoogle Scholar
  39. Yen, H.-C., Tuan, H.-L., & Liao, C.-H. (2011). Investigating the influence of motivation on students’ conceptual learning outcomes in web-based vs. classroom-based science teaching contexts. Research in Science Education, 41, 211–224. doi: 10.1007/s11165-009-9161-x.CrossRefGoogle Scholar

Copyright information

© Springer Science+Business Media Dordrecht 2017

Authors and Affiliations

  1. 1.Faculty of EducationMonash UniversityFrankstonAustralia
  2. 2.Foundation Chair of Early Childhood Education, Faculty of EducationMonash UniversityFrankstonAustralia

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