Bibliography – stcse students‘ and Teachers‘ Conceptions and Science Education Full Version fv09. rtf / March 23, 2009



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v. Aufschnaiter, C., Duit, R. (2004). Teachers' instructions and students' constructions in physics education: Using video to investigate how they match. In D. Zandvliet (Ed.), NARST Conference 2004, Conference Proceedings. Vancouver: NARST - National Association for Research in Science Teaching (CD Rom) // gp, P, VIDEO.

Vacc, N. N. (1999). Exploring fractal geometry with children. School Science and Mathematics, 99(2), 77-83 // g6,NONLIN,FRACTAL.

Valadares, J. (1993). Spontaneous thinking of secondary teachers about the relativity of mechanic magnitudes. In J. Novak (Ed.), Proceedings of the Third International Seminar on Misconceptions and Educational Strategies in Science and Mathematics. Ithaca, New York: Cornell University (distributed electronically) // g6,P,M.

Valanides, N. (1994). The process and effects of distillation among prospective elementary school teachers. Nicosia, Zypern: Department of Education, University of Cyprus // g8,C.

Valanides, N. (1999). Primary student teachers' conceptions on the transformations of matter during the process of distillation. In M. Komorek, Behrendt, H. , Dahncke, H. , Duit, R. , Graeber, W. , Kross, A. (Ed.), Research in Science Education - Past, Present, and Future Vol.2 (pp. 486-488). Kiel: IPN Kiel // g6,C.

Valk, A. E. v. d., Bormans, H. F. H. , Taconis, R. , Lijnse, P. L. (1990). The need for a particulate description of macroscopic energy phenomena. In P. L. Lijnse, Licht, P. , Vos, W. de, Waarlo, A. J. (Ed.), Relating macroscopic phenomena to microscopic particles: a central problem in secondary Science Education (pp. 294-303). Utrecht: CD-ß Press // g7,P,AT,EN.

Valk, A. E. v. d. (1992). Ontwikkeling in energieonderwijs. Utrecht: Uitgeverij CD-ß Press // g6,g7,P,EN.

Valk, T. v. d. (1989). Waves or particles? The cathode ray debate in the classroom. In R. Millar (Ed.), Doing science: Images of science in Science Education (pp. 160-179). London, New York, Philadelphia: The Falmer Press // g6,g7,P,Q,.

van Ackeren, I., Block, R., Klemm, K., Kullmann, H., & Sprütten, F. (2008). Schulkultur als Kontext naturwissenschaftlichen Lernens - Allgemeine und fachspezifische explorative Analysen. Zeitschrift für Pädagogik, 54(3), 341-360 // g1, g8, CTL.

van der Meij, J., & de Jong, T. (2006). Supporting students' learning with multiple representations in a dynamic simulation-based learning environment. Learning and Instruction, 16(3), 199-212 // g7, P, M, MMEDIA.

van der Valk, T., van Driel, J. H., & de Vos, W. (2007). Common characteristics of models in present-day scientific practice. Research in Science Education, 37(4), 469-488 // g6, MODEL, CSC.

van Driel, J., & Gräber, W. (2002). The teaching and learning of chemical equilibrium. In J. Gilbert, O. de Jong, R. Justi, D. F. Treagust & J. van Driel (Eds.), Chemical education: Towards research-based practice (pp. 271-292). Dordrecht: Kluwer Academic Publishers // g7, C.

van Driel, J. H., de Jong, O., Verloop, N. (2001). The development of preservice chemistry teachers' pedagical content knowledge. Science Education, 86(4), 572-590 // g8,CTL,PCK.

van Driel, J. H. (2002). Students' corpuscular conceptions in the context of chemical equilibrium and chemical kinetics. CERAPIE, 3(2), 201-213 // g7, C.

van Driel, J. H., Bulte, A. M. W., & Verloop, N. (2007). The relationships between teachers' general beliefs about teaching and learning and their domain specific curricular beliefs. Learning and Instruction, 17(2), 156-171 // g8, C, CTL.

van Eijck, M., & Roth, W.-M. (2007). Keeping the local local: Recalibrating the status of science and traditional ecological knowledge (TEK) in education. Science Education, 91(6), 926-947 // g1, SCON, ACTTH, B, ECOLOGY.

van Eijck, M., & Roth, W.-R. (2008). Representations of scientists in Canadian high school and college textbooks. Journal of Research in Science Teaching, 45(9), 1059-1082 // g1, TXT, CSC.

van Rens, L., Pilot, A., & van Dijk, H. (2004). Enhancement of quality in chemical inquiry by pre-university students. International Journal of Science and Mathematics Education, 2(4), 493-509 // g7, C.

van Rens, L. M. M., Dekkers, P. J. J. M. (2001). Learning about investigations - the teachers' role. In H. Behrendt, Dahncke, H. , Duit, R. , Graeber, W. , Komorek, M. , Kross, A. (Ed.), Research in Science Education - Past, Present, and Future (pp. 325-330). Dordrecht,The Netherlands: Kluwer Academic Publishers // g8,LAB,CTL.

van Zee, E., Lay, D., & Roberts, D. (2003). Fostering collaborative inquiries by prospective and practicing elementary and middle school teachers. Science Education, 87(4), 588-612 // g8, CTL.

van Zee, E. H. (2000). Analysis of a student-generated inquiry discussion. International Journal of Science Education, 22(2), 115-142 // g1,SCON,DISCOURSE,g7,P,AS,LPRO.

Vance, K., Miller, K. , Hand, B. (1995). Two constructivist approaches to teaching ecology at the middle school level. The American Biology Teacher, 57(4), 244-249 // g7,B.

Vanderlocht, M., Van Damme, J. (1989). Fouten en knelpunten bij het oplossen van problemen over de projectielbeweging. Tijdschrift voor Didactiek der ß-wetenschappen, 7(2), 115-137 // g6,P,M.

Varela, M., Wollman, W. (1987). Improving problem solving in a statewide physics program. Paper presented at the annual meeting of the NARST // g1.

Varela Nieto, P., Manrique de Campo, M. J. , Favieres Martinez, A. (1988). Circuitos electricos: Una aplicacion de un modelo de ensenanza-aprendizaje basado en las ideas previas de los alumnos. Ensenanza de las Ciencias, 6(3), 285-290 // g7,P,E.

Varela Nieto, P., Favieres Martinez, A. , Manrique del Campo, M. J. , Landazabal, M. C. P. de. (1993). Iniciacion a la Fisica en el marco de la teoria constructivista. Madrid: Centro de Publicaciones del Ministerio de Educacion y Ciencia // g1,g6,g7,P,E,EN,T.

Varelas, M. (1996). Between theory and data in a seventh-grade science class. Journal of Research in Science Teaching, 33(3), 229-263 // g1,g7,SCON,VYGOTSKY,P,BUOY,LPRO.

Varelas, M. (1997). Third and fourth graders' conceptions of repeated trials and best representations in science experiments. Journal of Research in Science Teaching, 34(9), 853-872 // g6,CSC,.

Varelas, M., Pineda, E. (1999). Intermingling and bumpiness: Exploring meaning making in the discourse of a science classroom. Research in Science Education, 29(1), 25-49 // g7,g8,P,M,FRICTION,DISCOURSE,CTL.

Varelas, M., Luster, B. , Wenzel, S. (1999). Meaning making in a community of learners: Struggles and possibilities in an urban science class. Research in Science Education, 29(2), 227-245 // g1,SCON,g7,CTL,DISCOURSE.

Varelas, M., Becker, J. , Luster, B. , Wenzel, S. (2002). When genres meet: Inquiry into a Six-Grade urban science class. Journal of Research in Science Teaching, 39(7), 579-605 // g7,P,M,LPRO.

Varelas, M., House, R., & Wenzel, S. (2005). Beginning teachers immersed into science: Scientist and science teacher identities. Science Education, 89(3), 492-516 // g8, CSC, CTL, LAB.

Varelas, M., Pappas, C. C., Kane, J. M., & Arsenault, A. (2007). Urban primary-grade children think and talk science: Curricular and instructional practices that nurture participation and argumentation. Science Education, 92(1), 65-95 // g6, g7, AFF, DISCOURSE, ARGUMENTATION.

Varelas, M., Pappas, C. C., & Rife, A. (2006). Exploring the role of intertextuality in concept construction: Urban second graders make sense of evaporation, boiling, and condensation. Journal of Research in Science Teaching, 43(7), 637-666 // g7, P, T, CHSTATE.

Varnai, A. S., Reinhold, P. (2004). Computerunterstütztes kooperatives Lernen in physikalischer Lernumgebung. In A. Pitton (Ed.), Chemie- und physikdidaktische Forschung und naturwissenschaftliche Bildung Band 24 (pp. 99-101). Münster: LIT Verlag // g7, MMEDIA.

Vázquez, A., Manassero-Mas, M. (1999). Students' ideas about the epistemology of science: models, laws and theories. In M. Komorek, Behrendt, H. , Dahncke, H. , Duit, R. , Graeber, W. , Kross, A. (Ed.), Research in Science Education - Past, Present, and Future Vol.1 (pp. 104-106). Kiel: IPN Kiel // g6,CSC.

Vázquez-Abad, J., Brousseau, N., Waldegg C., G., Vézina, M., Martinez D., A., & de Verjovsky, J. P. (2004). Fostering distributed science learning through collaborative technologies. Journal of Science Education and Technology, 13(2), 227-232 // g7, MMEDIA.

Vázquez-Alonso, A., Manassero-Mas, M.-A. (1999). Response and scoring models for the "Views on Science-Technology-Society" instrument. International Journal of Science Education, 21(3), 231-248 // g5,g6,CSC,STS.

Vazquez-Alonso, A., Manassero-Mas, M.-A., & Acevedo-Diaz, J.-A. (2006). An Analysis of complex multiple-choice science-technology-society items: Methodological development and preliminary results. Science Education, 90(4), 681-706 // g5.

Veal, W. R. (2004). Beliefs and knowledge in chemistry teacher development. International Journal of Science Education, 26(3), 329-351 // g8, CTL.

Veal, W. R., & Jackson, Z. (2006). Developing a primary science methods classroom. International Journal of Science and Mathematics Education, 4(2), 195-213 // g6, CTL, g8.

Veermans, K., van Jollingen, W., & de Jong, T. (2006). Use of heuristics to facilitate scientific discovery learning environment in a physics domain. International Journal of Science Education, 28(4), 341-361 // g7, P, M, FORCE, MMEDIA, INQUIRY.

Vegting, P. (1980). Education based on a new concept of teaching in physics. In W. F. Archenhold, Driver, R. , Orton, A. , Wood-Robinson, C. (Ed.), Cognitive development research in science and mathematics. Proceedings of an international seminar (pp. 320-327). Leeds: University of Leeds // g7,P.

Vegting, P. (1985). Concept development in pupils. In P. L. Lijnse (Ed.), The many faces of teaching and learning mechanics. Conference on physics education (pp. 290-302). Utrecht: GIREP/SVO/UNESCO // g6,P,M.

Vegting, P. (1988). Zijn misconcepties "mis"-concepties ? NUCN Maandblad, 13(4), 134-137 // g1.

Veiga, M. L., Costa Pereira, D. J. , 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 // g8,P,T,EN,ANA.

Velázquez-Marcano, A., Williamson, V., Ashkenazi, G., Tasker, R., & Williamson, K. C. (2004). The use of video demonstrations and particulate animation in general chemistry. Journal of Science Education and Technology, 13(3), 315-324 // g7, C, MMEDIA.

Vellom, R. P., Anderson, C. W. (1999). Reasoning about data in middle school science. Journal of Research in Science Teaching, 36(2), 179-200 // g7,GC,DISCOURSE,LPRO.

Venturini, P. (2007). The contribution of the theory of relation to knowledge to understanding students' engagement in learning physics. International Journal of Science Education, 29(9), 1065-1088 // g1, AFF, g7, P.

Venville, G. (1996). Learning about genetics: Using a multi-dimensional interpretive framework for understanding conceptual change. Paper presented at the annual meeting of AERA, New York, April 1996, 1-20 // g7,B,.

Venville, G., Treagust, D. (1996). Modelle und Analogien im Unterricht ueber Genetik an weiterfuehrenden Schulen. Zeitschrift fuer Didaktik der Naturwissenschaften, 2(1), 69-85 // g6,B,ANA.

Venville, G., Treagust, D. (1996). The role of analogies in promoting conceptual change in biology. Instructional Science, 24, 295-320 // g7,B,ANA.

Venville, G., Treagust, D. (1997). Analogies in biology education: A contentious issue. The American Biology Teacher, 59(5), 282-287 // g7,B,ANA.

Venville, G., Bryer, L. , Kilbourn, B. , Gilbert, J. K. (2002). Analogies. In J. Wallace, Louden, W. (Ed.), Dilemmas of science teaching (pp. 158-171). London: RoutledgeFalmer // g1,ANA.

Venville, G., Adey, P., Larkin, S., Robertson, A. (2003). Fostering thinking through science in the early years of schooling. International Journal of Science Education, 25(11), 1313-1331 // g7, GC.

Venville, G. (2004). Young children learning about living things: A case study of conceptual change from ontological and social perspectives. Journal of Research in Science Teaching, 41(5), 449-480 // g1, CC, g6, g7, B, LIFE.

Venville, G. (2004). Young children's intuitive knowledge about genetics concepts. Paper presented at the NARST Conference 2004, VANCOUVER // g6, B, GENETICS.

Venville, G., & Donovan, J. (2007). Developing year 2 students'-theory of biology with concepts of the gene and DNA. International Journal of Science Education, 29(9), 1111-1132 // g7, B, GENETICS.

Venville, G., Gribble, S. J., & Donovan, J. (2005). An exploration of young children's understandings of genetics concepts from ontological and epistemological perspectives. Science Education, 89(4), 614-633 // g6, B, GENETICS.

Venville, G., Rennie, L., & Wallace, J. (2004). Decision making and sources of knowledge: How students tackle integrated tasks in science, technology and mathematics. Research in Science Education, 34(2), 115-136 // g7, P, STS.

Venville, G. J., Bryer, L. , Treagust, D. F. (1994). Training students in the use of analogies to enhance understanding in science. Australian Science Teachers Journal, 40(2), 60-66 // g7,P,AT,ANA.

Venville, G. J., Treagust, D. F. (1999). Exploring conceptual change in genetics using a multidimensional interpretive framework. Journal of Research in Science Teaching, 35(9), 1031-1056 // g1,CON,AFF,g7,B.

Venville, G. J., Treagust, D. F. (2002). Teaching about the gene in the genetic information age. Australian Science Teachers' Journal, 48(2), 20-24 // g7, B, GENETICS.

Venville, G. J., Gribble, S. J., & Donovan, J. (2006). Metaphors for genes. In P. J. Aubusson, A. G. Harrison & S. M. Ritchie (Eds.), Metaphor and analogy in science education (pp. 79-92). Springer: Dordrecht, The Netherlands // g7, B, GENETICS, ANA.

Vergnaud, G., Halbwachs, F. , Rouchier, A. (1978). Structure de la matiere enseignee histoire des science et developement conceptuel chez l'eleve. Revue Francaise de Pedagogie, 45, 7-15 // g1,g3.

Verhoeff, R., Waarlo, A., & Boersma, K. (2008). Systems modelling and the development of coherent understanding of cell biology. International Journal of Science Education, 30(4), 543-568 // g7, B, MODEL.

Verjovsky, J., Waldegg, G. (2005). Analyzing beliefs and practices of a Mexican High School biology teacher. Journal of Research in Science Teaching, 42(4), 465-491 // g8, CTL.

Verkerk, G., Bouwens, R. E. A. (1993). Learning optics from seeing light. In L. C. Pereira, Ferreira, J. A. , Lopes, H. A. (Ed.), Light and Information.Proceedings of the 1993 GIREP International Conference on Physics Education (pp. 100-136). Braga, Portugal: GIREP // g6,g7,P,O.

Verschaffel, L., De Corte, E. , Lasure, S. (1999). Children´s conceptions about the role of real-world knowledge in mathematical modelling: analysis and improvement. In W. Schnotz, Vosniadou, S. , Carretero, M. (Ed.), New perspectives on conceptual change (pp. 175-189). Oxford, UK: Pergamon // g10.

Veslin, J. (1990). Les eleves de 11 ans peuvent-ils acceder a l'idee que "la science" est une creation de l'imaginaire des hommes ? In A. Giordan, Martinand, J. L. , Souchon, C. (Ed.), Actes JIES XII (pp. 85-91). Chamonix: Centre Jean Franco // g7,CSC.

Vhurumuku, E., Holtman, L., Mikalsen, O., & Kolsto, S. D. (2006). An investigation of Zimbabwe high school chemistry students' laboratory work-based images of the nature of science. Journal of Research in Science Teaching, 43(2), 127-149 // g7, C, LAB, CSC.

Vicentini-Missoni, M. (1979). Common sense knowledge and scientific knowledge. Paper presented at the conference "World Trends in Science Education", Halifax // g1.

Vicentini-Missoni, M. (1981). Earth and gravity: Comparison between adult's and children's knowledge. In W. Jung, Pfundt, H. , Rhoeneck, C. von (Ed.), Proceedings of the international workshop on "Problems Concerning Students' Representation of Physics and Chemistry Knowledge" (pp. 234-253). Ludwigsburg: Paedagogische Hochschule // g6,P,AS.

Vicentini-Missoni, M. (1983). Some issues for discussion from the point of view of science. Proceedings of USA-Italy Joint Seminar on Science Education Research // g1,g2.

Vicentini-Missoni, M. (1991). Intuitive or spontaneous pedagogy. In H. Wiesner (Ed.), Aufsaetze zur Didaktik der Physik II. Festschrift zum 65. Geburtstag von Walter Jung (pp. 259-266). Bad Salzdetfurth: Franzbecker // g1.

Vicentini-Missoni, M. (1993). Comment on the article "Studying conceptual change in learning physics" by Dykstra, Boyle, and Monarch. Science Education, 77(4), 461-463 // g1.

Vidar, T., Valdermo, O. (2001). Open-book and student portfolio learning and assessment. In D. Psillos, Kariotoglou, P. , Tselfes, V. , Bisdikian, G. , Fassoulopoulos, G. , Hatzikraniotis, E. , Kallery, M. (Ed.), Proceedings of the Third International Conference on Science Education Research in the Knowledge Based Society, Vol. 1 (pp. 368-370). Thessaloniki, Greece: Aristotle University of Thessaloniki // g7,g8,CTL.

Viennot, L. (1974). Sens physique et raisonnement formel in dynamique elementaire. Encart Pedagogique, 35-46 // g6,P,M.

Viennot, L. (1976). Mouvement et force chez les etudiants de premier cycle universitaire. Le pendule simple. Bulletin de la Societe Francaise de Physique. Encart Pedagogique, 2, 35-46 // g6,P,M.

Viennot, L. (1978). Le raisonnement spontane en dynamique elementaire. Revue Francaise de Pedagogie, 45, 16-24 // g6,P,M.

Viennot, L. (1979). Le raisonment spontane en dynamique elementaire. Paris: Herman // g6,P,M.

Viennot, L. (1979). Spontaneous reasoning in elementary dynamics. European Journal of Science Education, 1(2), 205-221 // g6,P,M.

Viennot, L. (1980). Spontaneous reasoning in elementary dynamics. In W. F. Archenhold, Driver, R. , Orton, A. , Wood-Robinson, C. (Ed.), Cognitive development research in science and mathematics. Proceedings of an international seminar (pp. 273-274). Leeds: University of Leeds // g6,P,M.

Viennot, L. (1981). Common practice in elementary algebra. Journal of Research in Science Teaching, 3, 183-194 // g6.

Viennot, L. (1981). The implication of mathematical structure versus physical content: Report on a research done by S. Fauconnet. In W. Jung, Pfundt, H. , Rhoeneck, C. von (Ed.), Proceedings of the international workshop on "Problems Concerning Students' Representation of Physics and Chemistry Knowledge" (pp. 79-91). Ludwigsburg: Paedagogische Hochschule // g6,P.

Viennot, L. (1983). Implicit statements in physics: Students and constants. In H. Helm, Novak, J. D. (Ed.), Proceedings of the International Seminar "Misconceptions in Science and Mathematics" (pp. 133-137). Ithaca, N. Y.: Cornell University // g6,P.

Viennot, L. (1983). Implicit statements in physics: Students and constants. Research on Physics Education. Proceedings of the first international workshop. La Londe les Maures, 355-361 // g6,P.

Viennot, L. (1983). Natural tendencies in analysing students' reasoning two instances in mechanics. In H. Helm, Novak, J. D. (Ed.), Proceedings of the International Seminar "Misconceptions in Science and Mathematics" (pp. 239-244). Ithaca, N. Y.: Cornell University // g1,g6,P,M.

Viennot, L. (1985). Analysing students' reasoning in science: A pragmatic view of theoretical problems. European Journal of Science Education, 7(2), 151-162 // g1,g5,g6,P,M.

Viennot, L. (1985). Analyzing students' reasoning: Tendencies in interpretation. American Journal of Physics, 53, 432-436 // g6,P,M.

Viennot, L. (1991). Students ideas and common experience: A direct link ? Examples in geometrical optics. In H. Wiesner (Ed.), Aufsaetze zur Didaktik der Physik II. Festschrift zum 65. Geburtstag von Walter Jung (pp. 267-273). Bad Salzdetfurth: Franzbecker // g6,P,O.

Viennot, L., Rainson, S. (1992). Students' reasoning about the superposition of electric fields. International Journal of Science Education, 14(4), 475-487 // g6,P,E.

Viennot, L. (1994). Fundamental patterns in common reasoning: Examples in physics. TDß, 12(2), 89-103 // g6,P,GC.

Viennot, L. (1994). Fundamental patterns in common reasoning: Examples in physics. In P. L. Lijnse (Ed.), European research in Science Education - Proceedings of the first Ph. D. Summerschool (pp. 33-47). Utrecht: CDß Press, Centrum voor ß-Didactiek // g6,GC,P.

Viennot, L., Rozier, S. (1994). Pedagogical outcomes of research in science education: Examples in mechanics and thermodynamics. In P. Fensham, Gunstone, R. , White, R. (Ed.), The content of science (pp. 237-254). London: The Falmer Press // g6,g7,P,M,T.

Viennot, L. (1995). A multidimensional approach to characterise a conceptual 'state' in students: The role played by questions. In D. Psillos (Ed.), European Research in Science Education II (pp. 178-187). Thessaloniki: Art of Text S. A. // g5.

Viennot, L., Chauvet, F. (1997). Two dimensions to characterize research-based teaching strategies: Examples in elementary optics. International Journal of Science Education, 19(10), 1159-1168 // g7,P,O,.

Viennot, L. (1998). Comment on students' conceptions and problem solving in mechanics. In A. Tiberghien, Jossem, E. , Barojas, J. (Ed.), Connecting research in physics education (pp. 1-2). Ohio: ICPE Books // g6,g7,P,M,FORCE.

Viennot, L. (1998). Experimental facts and ways of reasoning in thermodynamics: Learners' common approach. In A. Tiberghien, Jossem, E. , Barojas, J. (Ed.), Connecting research in physics education (pp. 1-10). Ohio: ICPE Books // g6,g7,P,T.

Viennot, L., Rainson, S. (1999). Design and evaluation of a research-based teaching sequence: The superposition of electric field. International Journal of Science Education, 21(1), 1-16 // g7,P,E,ESTAT,GC.

Viennot, L. (2001). Anticipating teachers' reactions to innovative sequences examples in optics. In R. Pinto, Surinach, S. (Ed.), Physics Teacher Education Beyond 2000 (pp. 65-72). Paris: Elsevier // g8,CTL,P,O,LIGHT.

Viennot, l. (2001). Relating research in didactics and actual teaching practice: Impact and virtues of critical details. In D. Psillos, Kariotoglou, P. , Tselfes, V. , Bisdikian, G. , Fassoulopoulos, G. , Hatzikraniotis, E. , Kallery, M. (Ed.), Proceedings of the Third International Conference on Science Education Research in the Knowledge Based Society, Vol. 1 (pp. 22-26). Thessaloniki, Greece: Aristotle University of Thessaloniki // g8,g9,CTL.

Viennot, L. (2003). Relating research in didactics and actual teaching practice: Impact and virtues of critical details. In D. Psillos, Kariotoglou, P., Tselfes, V., Hatzikraniotis, E., Fassoulopoulos, G., Kallery, M. (Ed.), Science education research in the knowledge-based society (pp. 383-393). Dordrecht, The Netherlands: Kluwer Academic Publishers // g8, CTL.

Viennot, L., Chauvet, F., Colin, P., & Rebmann, G. (2005). Designing strategies and tools for teacher training: The role of critical details, examples in optics. Science Education, 89(1), 13-27 // g8, P, O, CTL, g9.

Viennot, L., & Kaminski, W. (2006). Can we evaluate the impact of a critical detail? The role of a type of diagram in understanding optical imaging. International Journal of Science Education, 28(15), 1867-1886 // g7, P, O.



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