FUTURE PRESCHOOL TEACHERS’ ATTITUDES TOWARDS THE INTEGRATION OF THE STEM LEARNING APPROACH IN EARLY CHILDHOOD PRACTICE

STEM/ STEAM/ STREAM APPROACH IN THEORY AND PRACTICE OF CONTEMPORARY EDUCATION, 2025 (pp. 157-168)

AUTHOR(S) / AUTOR(I): Gordana M. Stepić

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DOI: 10.46793/STREAM25.157S

ABSTRACT / SAŽETAK:

The research aims to assess the attitudes of future preschool teachers toward the integration of the STEM learning approach in early childhood practice before and after the introduction of the Conceptual PlayWorld model (CPW). The sample of the research is future preschool teachers (N=46) who attended the obligatory course Methodical Practicum of Getting to Know the Environment (MPGKE) and the optional subject Children’s Play and Creativity (CPC) during which they developed the CPW, as a model of the integration of the STEM learning approach in early childhood practice. The attitudes of future preschool teachers were examined using a five-point Likert-type scale. The findings indicate that this model can create conditions for a positive shift in the attitudes of future preschool teachers towards the application of the STEM learning approach in preschool age, that it can be one of the models for the application of the STEM learning approach in early childhood practice, aligned with the understanding of learning and development of preschool children and that it needs to be further studied and developed in our educational context.

KEYWORDS / KLJUČNE REČI:

STEM learning approach, Conceptual PlayWorld (CPW), future preschool teachers, early childhood practice

REFERENCES / LITERATURA: 

  • Ata Aktürk, A., Demircan, H. Ö., Şenyurt, E., & Çetin, M. (2017). Turkish early childhood education curriculum from the perspective of STEM education: A document analysis. Journal of Turkish Science Education, 14(4): 16–34. Available at: https://doi.org/10.36681/
  • Baigiati, A., & Evangelou, D. (2015). Engineering curriculum in the preschool classroom: The teacher’s experience. European Early Childhood Education Research Journal, 23(1): 112–128. Available at: https://doi.org/10.1080/1350293X.2014.991099
  • Banko, W., Grant, M. L., Jabot, M. E., McCormack, A. J., & O’Brien, T. (2013). Science for the next generation: Preparing for the new standards, National Science Teachers Association (NSTA) Press.
  • Barenthien, J., M, Lindner., Ziegler, T., & Steffensky, M. (2020). Exploring preschool teachers’ science-specific knowledge. Early Years, 40(3): 335–350. Available at: https://doi.org/10.1080/09575146.2018.1443321  10.1080/09575146.2018.1443321
  • DeJarnette, N. K. (2018). Implementing STEAM in the Early Childhood Classroom. European Journal of STEM Education, 3(3), 18. Available at: https://doi.org/10.20897/ejsteme/3878
  • Elkonin, D. B. (2005). The Psychology of Play. Journal of Russian & East European Psychology, 43(1): 11–21.
  • 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. Available at: https://doi.org/10.2304/ciec.2011.12.3.224
  • Fleer, M. (2017a). Scientific playworlds: A model of teaching science in play-based settings. Research in Science Education, 49(2): 1–22. DOI: 10.1007/s11165-017-9653-z
  • Fleer, M. (2017b). Digital playworlds in an Australia context. In: Bruce, T., Bredikyte, M., & Hakkarainen, P. (eds.), Routledge handbook of play in early childhood, UK: Routledge Press, Taylor and Francis Group, 289–304.
  • Fleer, M. (2018). Conceptual Playworlds: the role of imagination in play and learning. Early Years, 41(4): 353–364. Available at: https://doi.org/10.1080/09575146.2018.1549024
  • Fleer, M. (2019). Conceptual PlayWorlds as a pedagogical intervention: Supporting the learning and development of the preschool child in play-based setting. Obutchénie, 3(3): 1–22. Available at: https://doi.org/10.14393/OBv3n3.a2019-51704
  • Fleer, M. (2020). Studying the relations between motives and motivation — How young children develop a motive orientation for collective engineering play. Learning, Culture and Social Interaction, 24. Available at: https://doi.org/10.1016/j.lcsi.2019.100355
  • Fleer, Μ., Fragkiadaki, G., & Rai, R. (2020). Programmatic research in the Conceptual PlayLab: STEM PlayWorld as an educational experiment and as a source of development. Science Education: Research & Praxis, 76: 9–23.
  • Fleer, M., Fragkiadaki, G., & Rai, P. (2021). The place of theoretical thinking in professional development: Bringing science concepts into play practice. Learning, Culture and Social Interaction, 32(2). Available at: https://doi.org/10.1016/j.lcsi.2019.100372
  • Fleer, M. (2022). How Conceptual PlayWorlds Create Different Conditions for Children’s Development Across Cultural Age Periods – A Programmatic Study Overview. New Ideas in Child and Educational Psychology, 2(1/2): 3–29. DOI: 10.11621/nicep.2022.0201
  • Fleer, M., Allen, K., Clerc-Georgy, A., Disney, L., Li, L., McKinley, L., Quinones, G., Rai, P., Scull, J., & Suryani, A. (2023). Why Play Works: Conceptual PlayWorlds Inspiring Learning, Imagination and Creativity in Education, Melbourne: Monash University.
  • Gomes, J., & Fleer, M. (2017). The development of a scientific motive: How preschool science and home play reciprocally contribute to science learning. Research in Science Education, 49(2): 613–634.
  • Hadley, F., Waniganayake, M., & Shepherd, W. (2015). Contemporary practice in professionallearning and development of early childhood educators in Australia: Reflection on whatworks and why. Professional Development in Education, 41(2): 187–202. Available at: https://doi.org/10.1080/19415257.2014.986818
  • Jamil, F. M., Linder, S. M., & Stegelin, D. A. (2018). Early childhood teacher beliefs about STEAM education after a professional development conference. Early Childhood Education Journal, 46 (4): 409–417. Available at: https://doi.org/10.1007/s10643-017-0875-5
  • John, M. S., Sibuma, B., Wunnava, S., Anggoro, F., & Dubosarsky, M. (2018). An iterative participatory approach to developing an early childhood problem-based STEM curriculum. European Journal of STEM Education, 3(3), 07. https://doi.org/10.20897/ejsteme/3867
  • Lindqvist, G. (1995). The aesthetics of play: A didactic study of play and culture in preschools. Stockholm, Sweden: Gotab.
  • Moomaw, S., & Davis, J. (2010). STEM comes to preschool. Young Children, 65(5), 12-18.
  • Nuttall, J., Edwards, S., Mantilla, A., Grieshaber, S., & Wood, E. (2015). The role of motive objects in early childhood teacher development concerning children’s digital play and play-based learning in early childhood curricula. Professional Development in Education, 41(2): 222–235. Available at: https://doi.org/10.1080/19415257.2014.990579
  • Park, M. H., Dimitrov, D. M., Patterson, L. G., & Park, D. Y. (2017). Early childhood teachers’ beliefs about readiness for teaching science, technology, engineering, and mathematics. Journal of Early Childhood Research, 15(3): 275–291. Available at: https://doi.org/10.1177/1476718X15614040
  • Simoncini, K., & Lasen, M. (2018). Ideas about STEM among Australian early childhood professionals: How important is STEM in early childhood education? International Journal of Early Childhood, 50(3): 353–369. Available at: https://doi.org/10. 1007/s13158-018-0229-5
  • Siry, C., & Kremer, I. (2011). Children explain the rainbow: using young children’s ideas to guide science curricula. International Journal of Science Education and Technology, 20(5): 643–655. Available at:  https://doi.org/10.1007/s10956-011-9320-5
  • Stephenson, T., Fleer, M., Fragkiadaki, G., & Rai, P. (2021). Teaching STEM through play: conditions created by the conceptual PlayWorld model for early childhood teachers. Early Years, 43(4-5): 811–827. Available at: https://doi.org/10.1080/09575146.2021.2019198
  • Tank, K. M., Rynearson, A. M., & Moore, T. J. (2018). Examining student and teacher talk within engineering design in kindergarten. European Journal of STEM Education, 3(3), 10. Available at: https://doi.org/10.10/20897/ejsteme/3870
  • Tippett, C.D., & Milford, T.M. (2017). Findings from a Pre-kindergarten Classroom: Making the Case for STEM in Early Childhood Education.  International Journal of Science and Mathematics Education, 15(1): 67–86. Available at: https://doi.org/10.1007/s10763-017-9812-8
  • Vygotsky, L. S. (1966). Play and its role in the mental development of the child. Voprosy psikhologii, 12(6): 62–76.
  • Wan, Z.H., Jiang, Y., & Zhan, Y. (2020). STEM Education in Early Childhood: A Review of Empirical Studies, Early Education and Development, 32(2): 1–23 DOI: 10.1080/10409289.2020.1814986
  • Zendler, A., Seitz, C., & Klaudt, D. (2018). Instructional methods in STEM education: A cross-contextual study. EURASIA Journal of Mathematics, Science and Technology Education, 14(7): 2969–2986. Available at: https://doi.org/10.29333/ejmste/91482