In this article, we draw upon the Conceptual Profile Theory to discuss the negotiation of meanings related to the energy concept in an 11th grade physics classroom. This theory is based on the heterogeneity of verbal thinking, that is, on the idea that any individual or society does not represent concepts in a single way. According to this perspective, the processes of conceptualization consist of the use of a repertoire of different socially stabilized signifiers, adjusted to the context in which they occur. We start by proposing zones of a conceptual profile model for energy, each zone being characterized by its own commitments and identifiable by certain modes of talking about energy. Based on classroom evidence, we claim that teachers and students negotiate meanings that interpenetrate the domains of everyday and scientific knowledge. Being inevitable and necessary, this heterogeneity of conceptual thinking needs to be considered in teaching design in order to allow its awareness on the part of the students. We argue that students’ conceptual development goals should be considered in terms of general goals of science education, which points to the need of overcoming the encapsulation of scientific school knowledge. We show that the Conceptual Profile Theory provides a basis for science education that can promote the crossing of cultural boundaries, seeking relations between science and the spheres of everyday life.
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By mode of conceptualization we are referring to the different status of concepts in the domain of everyday life knowledge and scientific knowledge. In science, concepts are theoretical units that are part of a structure of knowledge that is focus of a deliberate analysis. In the realm of everyday life, concepts are much more elusive, flexible, and oriented to practical action.
Contrary to Solomon, we recognize that there is more than a single domain of science. There is much polysemy in the scientific interpretations of energy, and some of these interpretations are nearly exclusive to specific scientific subdomains, e.g., physics, chemistry, geology, ecology, and molecular biology. We address this later in the article.
The methodological grounds for the proposal of the zones of the conceptual profile of energy extrapolate the objectives of this paper.
To elaborate this representation, we were inspired by Solomon’s (1992) mapping of energy themes. However, Solomon presents a mapping of contexts, not of concepts. She also does not establish relations between the spheres of general knowledge and scientific knowledge.
This is, in some ways, analogous to the sense that matter comes in many forms (e.g., different phases of the same matter or different allotropes of an element). However, the forms-of-matter analogy is not mapped to energy in many forms when considering types of matter (e.g., different elements or structural isomers with the same molecular formula) vs. types of energy, since conservation of energy provides for transformations between types of energy, while conservation of matter does not uniformly imply the same for matter (e.g., elements do not change identity, though structural isomers can sometimes be interconverted).
We reproduce the sentences in the way they were annotated by the teacher (including quotation marks); they reveal both the students’ ways of talking and the importance the teacher attributed to them. We added codes in parentheses (Z1 to Z5) referring to the zones of the energy concept profile, and numbers (1 to 10), to facilitate references in the text.
This activity as well the proposal of the ramp experiment was taken from the book “Energizing Physics” (Osowiecki and Southwick 2012).
Aguiar, O. G. (2014). The implications of the conceptual profile in science teaching: An example from a teaching sequence in thermal physics. In E. Mortimer & C. El-Hani (Eds.), Conceptual profiles: A theory of teaching and learning scientific concepts (pp. 235–259). Dordrecht: Springer.
Aguiar, O., Sevian, H., & Balicki, S. (2019). Chemistry teachers’ intentions and students’ epistemic agency in communicative patterns in the classroom. Paper to be presented at NARST, Baltimore, Maryland, USA. (Forthcoming).
Ametller, J., & Pintó, R. (2002). Students' reading of innovative images of energy at secondary school level. International Journal of Science Education, 24(3), 285–312.
Araujo, A. (2014). O perfil conceitual de calor e seus usos por comunidades situadas. (Tese de Doutorado). Faculdade de Educação da UFMG. Belo Horizonte, 223 p.
Bachelard, G. (2002). The formation of the scientific mind: A contribution to a psychoanalysis of objective knowledge. Manchester: Clinamen.
Berger, P. L., & Luckmann, T. (1967). The social construction of reality: A treatise in the sociology of knowledge. London: Allen Lane.
Bliss, J., & Ogborn, J. (1985). Children’s choices of uses of energy. European Journal of Science Education, 7, 195–203.
Brook, A. (1986). Children's understanding of energy a review of literature. In R. Driver & R. Millar (Eds.), Energy Matters: Proceedings of an invited conference: Teaching about energy within the secondary science curriculum (pp 33–46). Leeds: University of Leeds, Centre for Studies in Science and Mathematics Education.
Brookes, D. T., & Etkina, E. (2007). Using conceptual metaphor and functional grammar to explore how language used in physics affects student learning. Physical Review Special Topics - Physics Education Research, 3(1), 010105.
Bunge, M. (2000). Energy: Between physics and metaphysics. Science & Education, 9(5), 459–463.
Caravita, S., & Halldén, O. (1994). Re-framing the problem of conceptual change. Learning and Instruction, 4(1), 89–111.
Chen, R. F., Eisenkraft, A., Fortus, D., Krajcik, J., Neumann, K., Nordine, J., & Scheff, A. (Eds.). (2014). Teaching and learning of energy in K-12 education. New York: Springer.
Chi, M. T., Slotta, J. D., & De Leeuw, N. (1994). From things to processes: A theory of conceptual change for learning science concepts. Learning and Instruction, 4(1), 27–43.
Coelho, R. L. (2009). On the concept of energy: How understanding its history can improve physics teaching. Science & Education, 18(8), 961–983.
Coopersmith, J. (2015). Energy, the subtle concept: The discovery of Feynman's blocks from Leibniz to Einstein. USA: Oxford University Press.
Crepalde, R. S., & Aguiar Jr., O. (2013). A formação de conceitos como ascensão do abstrato ao concreto: da energia pensada à energia vivida. Investigações em Ensino de Ciências, 18(02), 299–325.
Crepalde, R. S., & Aguiar Jr., O. (2018). O híbrido energia enunciado por professores de física e biologia em formação inicial. Educação em Revista. https://doi.org/10.1590/0102-4698184028.
Dauer, J. M., Miller, H. K., & Anderson, C. W. A. (2014). Conservation of energy: An analytical tool for student accounts of carbon-transforming processes. In R. Chan et al. (Eds.), Teaching and learning of energy in K–12 education (pp. 47–61). Cham: Springer.
Driver, R., & Millar, R. (Eds.). (1986). Energy matters: Proceedings of an invited conference: Teaching about energy within the secondary science curriculum. Leeds: University of Leeds, Centre for Studies in Science and Mathematics Education..
Driver, R., Squires, A., Rushworth, P., & Wood-Robinson, V. (1994). Making sense of secondar science: Research into children’s ideas. London/New York: Routledge.
Duit, R. (1984). Learning the energy concept in school – Empirical results from the Philippines and West Germany. Physics Education, 19(2), 59–66.
Duit, R. (1986), In search of an energy concept. In R. Driver & R. Millar (Eds.), Energy Matters: Proceedings of an invited conference: Teaching about energy within the secondary science curriculum (pp 67–101). Leeds: University of Leeds, Centre for Studies in Science and Mathematics Education.
El-Hani, C. N., & Emmeche, C. (2000). On some theoretical grounds for an organism-centered biology: Property emergence, supervenience, and downward causation. Theory in Biosciences, 119(3–4), 234–275.
El-Hani, C. N., da Silva-Filho, W. J., & Mortimer, E. F. (2014). The epistemological grounds of the conceptual profile theory. In E. Mortimer & C. El-Hani (Eds.), Conceptual profiles: A theory of teaching and learning scientific concepts (pp. 35–65). Dordrecht: Springer.
Elkana, Y. (1974). The discovery of the conservation of energy. Cambridge: Harvard University Press.
Ellse, M. (1988). Transferring, not transforming energy. School Science Review, 69(248), 427–437.
Engeström, Y. (1991). Non scolae sed vitae discimus: Toward overcoming the encapsulation of school learning. Learning and Instruction, 1(3), 243–259.
Feynman, R.P., Leighton, R.B., & Sands, M. (1966). The Feynman Lectures on Physics. Reading: Addison Wesley.
Guidoni, P. (1985). On natural thinking. European Journal of Science Education, 7(2), 133–140.
Gupta, A., Hammer, D., & Redish, E. F. (2010). The case for dynamic models of learners' ontologies in physics. The Journal of the Learning Sciences, 19(3), 285–321.
Hammer, D., Gupta, A., & Redish, E. F. (2011). On static and dynamic intuitive ontologies. The Journal of the Learning Sciences, 20(1), 163–168.
Hewson, M. G., & Hamlyn, D. (1984). The influence of intellectual environment on conceptions of heat. European Journal of Science Education, 6(3), 245–262.
Holman, J. (1986). Teaching about energy – the chemical perspective. In R. Driver & R. Millar (Eds.), Energy Matters: Proceedings of an invited conference: Teaching about energy within the secondary science curriculum (pp 47–52). Leeds: University of Leeds, Centre for Studies in Science and Mathematics Education.
Hutchison, P., & Hammer, D. (2010). Attending to student epistemological framing in a science classroom. Science Education, 94(3), 506–524.
Jewett Jr., J. W. (2008). Energy and the confused student IV: A global approach to energy. The Physics Teacher, 46(4), 210–217.
Jin, H., & Anderson, C. W. (2012). A learning progression for energy in socio-ecological systems. Journal of Research in Science Teaching, 49(9), 1149–1180.
Jin, H., & Wei, X. (2014). Using ideas from the history of science and linguistics to develop a learning progression for energy in socio-ecological systems. In R. Chan et al. (Eds.), Teaching and learning of energy in K–12 education (pp. 157–173). Cham: Springer.
Kuhn, T. (1977). The concept of cause in the development of Physics. In T. Kuhn (Eds.), The Essential Tension: Selected Studies in Scientific Teadition and Change (pp. 21–30). Chicago: The University of Chicago Press.
Lacy, S., Tobin, R. G., Wiser, M., & Crissman, S. (2014). Looking through the energy lens: A proposed learning progression for energy in grades 3–5. In R. Chan et al. (Eds.), Teaching and learning of energy in K–12 education (pp. 241–265). Cham: Springer.
Lakoff, G. (1987). Women, fire, and dangerous things. Chicago: University of Chicago Press.
Lakoff, G., & Johnson, M. (2003). Metaphors we live by. Chicago: University of Chicago Press.
Lancor, R. A. (2014). Using student-generated analogies to investigate conceptions of energy: A multidisciplinary study. International Journal of Science Education, 36(1), 1–23.
Lijnse, P. (1990). Energy between the life-world of pupils and the world of physics. Science Education, 74(5), 571–583.
Linder, C. J. (1993). A challenge to conceptual change. Science Education, 77(3), 293–300.
Liu, X., & Park, M. (2014). Contextual dimensions of the energy concept and implications for energy teaching and learning. In R. Chan et al. (Eds.), Teaching and learning of energy in K–12 education (pp. 175–186). Cham: Springer.
Louisa, M., Veiga, F. C. S., Pereira, D. J. C., & Maskill, R. (1989). Teachers’ language and pupils’ ideas in science lessons: Can teachers avoid reinforcing wrong ideas? International Journal of Science Education, 11(4), 465–479.
Mayr, E. (1997). This is biology: the science of the living world. Cambridge: Harvard University Press.
Millar, R. (2014). Towards a research-informed teaching sequence for energy. In R. Chan et al. (Eds.), Teaching and learning of energy in K–12 education (pp. 187–206). Cham: Springer.
Mortimer, E. F. (1995). Conceptual change or conceptual profile change? Science & Education, 4(3), 267–285.
Mortimer, E. F., & El-Hani, C. N. (Eds.). (2014). Conceptual profiles: A theory of teaching and learning scientific concepts. Dordrecht: Springer.
Mortimer, E. F., & Wertsch, J. V. (2003). The architecture and dynamics of intersubjectivity in science classrooms. Mind, Culture, and Activity, 10(3), 230–244.
Mortimer, E. F., Scott, P., & El-Hani, C. N. (2012). The heterogeneity of discourse in science classrooms: The conceptual profile approach. In B. Fraser, K. Tobin & C. McRobbie (Eds.), Second international handbook of science education (pp. 231–246). Dordrecht: Springer.
National Research Council. (2012). A framework for K-12 science education: Practices, cross- cutting concepts, and core ideas (Core idea PS3 energy) (pp. 120–130). Washington, DC: The National Academies Press.
Neumann, K., Viering, T., Boone, W. J., & Fischer, H. E. (2013). Towards a learning progression of energy. Journal of Research in Science Teaching, 50(2), 162–188.
Next Generation Science Standards Lead States (2013). Next generation science standards (NGSS): Achieve, Inc. on behalf of the twenty-six states and partners that collaborated on the NGSS. Retrieved from http://www.nextgenscience.org/next-generation-science-standards. Accessed 15 March 2018.
Ogborn, J. (1986). Energy and fuel – the meaning of ‘the go of things’. In R. Driver & R. Millar (Eds.), Energy Matters: Proceedings of an invited conference: Teaching about energy within the secondary science curriculum (pp. 59–66). Leeds: University of Leeds, Centre for Studies in Science and Mathematics Education.
Ogborn, J., Kress, G., Martins, I., & McGillicuddy, K. (1996). Explaining science in the classroom. Maidenhead: Open University Presss.
Osowiecki, A., & Southwick, J. (2012). Energizing Physics: An Introductory Physics Course. Pilot version 2. Boston: NSF (https://sites.google.com/site/epcourse/energizing-physics).
Pacca, J. L., & Henrique, K. F. (2004). Dificultades y estrategias para la enseñanza del concepto de energía. Enseñanza de las ciencias, 22(1), 159–166.
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(2), 211–227.
Rozier, S., & Viennot, L. (1991). Students’ reasonings in thermodynamics. International Journal of Science Education, 13(2), 159–170.
Scherr, R. E., & Robertson, A. D. (2015). Productivity of “collisions generate heat” for reconciling an energy model with mechanistic reasoning: A case study. Physical Review Special Topics - Physics Education Research, 11(1), 010111.
Scott, P. H., Mortimer, E. F., & Aguiar, O. G. (2006). The tension between authoritative and dialogic discourse: A fundamental characteristic of meaning making interactions in high school science lessons. Science Education, 90(4), 605–631.
Seeley, L., Vokos, S., & Minstrell, J. (2014). Constructing a sustainable Foundation for Thinking and Learning about Energy in the twenty-first century. In R. Chan et al. (Eds.), Teaching and learning of energy in K–12 education (pp. 337–356). Cham: Springer.
Simões Neto, J. E. (2016). Uma proposta para o perfil conceitual de energia em contextos de Ensino da Física e da Química. (Doctoral dissertation), Departamento de Educação, Universidade Federal Rural de Pernambuco, Recife.
Slotta, J. D., Chi, M. T., & Joram, E. (1995). Assessing students' misclassifications of physics concepts: An ontological basis for conceptual change. Cognition and Instruction, 13(3), 373–400.
Smith, C. (1998). The science of energy: A cultural history of energy physics in Victorian Britain. Chicago: University of Chicago Press.
Solomon, J. (1987). Social influences on the construction of pupils' understanding of science. Studies in Science Education, 14(1), 63–82.
Solomon, J. (1992). Getting to know about energy in school and society. London: Routledge.
Szteinberg, G., Balicki, S., Banks, G., Clinchot, M., Cullipher, S., Huie, R., et al. (2014). Collaborative professional development in chemistry education research: Bridging the gap between research and practice. Journal of Chemical Education, 91(9), 1401–1408.
Tobin, R. G., Lacy, S. J., Crissman, S., & Haddad, N. (2018). Model-based reasoning about energy: A fourth-grade case study. Journal of Research in Science Teaching, 00, 01–28.
Trumper, R. (1990). Being constructive: An alternative approach to the teaching of the energy concept--part one. International Journal of Science Education, 12(4), 343–354.
Vygotsky, L.S. (1987). The collected works of L.S. Vygotsky. Volume 1: Problems of general psychology. Including the Volume Thinking and speech. New York: Plenum.
Watts, D. M. (1983). Some alternative views of energy. Physics Education, 18(5), 213.
Wei, R., Reed, W., Hu, J., & Xu, C. (2014). Energy spreading or disorder? Understanding entropy from the perspective of energy. In R. Chan et al. (Eds.), Teaching and learning of energy in K–12 education (pp. 317–335). Cham: Springer.
Wells, G. (2008). Learning to use scientific concepts. Cultural Studies of Science Education, 3, 329–350.
Wertsch, J. V. (1985). Vygotsky and the social formation of mind. Cambridge: Harvard University Press.
Wiser, M., & Carey, S. (1983). When heat and temperature were one. In D. Gentner & A. Stevens (Eds.), Mental models (pp. 267–297). Hillsdale: Lawrence Erlbaum Associates.
The authors are grateful to the teacher, codenamed Terra, who welcomed OA into her classroom to observe and interview her students and her.
Funding that supported this work was provided to the first and second authors (OA and HS): United States National Science Foundation award DRL-1621228, first and third authors (OA and CE-H): the Brazilian National Council for Scientific and Technological Development (Conselho Nacional de Desenvolvimento Científico e Tecnológico, CNPq) for Productivity in Research Fellowships (309361/2016-8 and 303011/2017-3, respectively), and third author (CE-H): research funding for the National Institute of Science and Technology (Instituto Nacional de Ciência e Tecnologia, INCT) project by CNPq award 465767/2014-1 and a Coordination for the Improvement of Higher Education Personnel (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior, CAPES) award 23038.000776/2017-54.
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The authors declare that they have no conflict of interest.
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Aguiar, O., Sevian, H. & El-Hani, C.N. Teaching About Energy. Sci & Educ 27, 863–893 (2018). https://doi.org/10.1007/s11191-018-0010-z