Asia-Pacific Forum on Science Learning and Teaching, Volume 19, Issue 1, Article 14 (Jun., 2018)
Hasan Sahin KIZILCIK and Mustafa TAN
A qualitative research of the conceptual learning process of the heat concept

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References

Adawi, T., Berglund, A., Booth, S. & Ingerman, A. (2001). Context in Phenomenographic Research on Understanding Heat and Temperature, The 9th EARLI Conference, Fribourg, August.

Altunışık, R., Coşkun, R., Yıldırım, E. & Bayraktaroğlu, S. (2002). Research Methods in Social Sciences, 2nd Edition, Adapazarı: Sakarya Kitabevi

Arnold, M. & Millar, R. (1996). Learning the scientific "story": A case study in the teaching and learning of elementary thermodynamics. Science Education, 80(3), 249–81.

Aydoğan, S., Güneş, B. & Gülçiçek, Ç. (2003). The Misconceptions about Heat and Temperature, The Journal of Gazi Educational Faculty, 23, 111-124.

Başer, M. (2006). Fostering Conceptual Change By Cognitive Conflict Based Instruction On Students' Understanding Of Heat And Temperature Concepts, Eurasia Journal of Mathematics, Science and Technology Education, 2(2), July, 96-114.

Başer, M. & Geban, Ö. (2007). The effectiveness of conceptual change instruction on the understanding of heat and temperature concepts. Research in Science and Technological Education, 25, No.1, 115–133.

Bodner, G. M. (1986). Constructivism: A theory of knowledge. Journal of Chemical Education, 63, 873-878.

Campanario, J.M. (2002). Ther Parallelism Between Scientist' and Students' Resistance to New scientific ideas. International Journal of Science Education, 24(10), 1095-1110.

Carlton, K. (2000). Teaching about heat and temperature, Physics Education, 35(2) March, 101-105.

Ceylan, H. (2008). The effect of conceptual change approach on teaching the subject of electricity to sixth-grade students in primary education science and technology course. Unpublished Master thesis, Gazi University, Ankara.

Clough, E. E. & Driver, R. (1985). Secondary students' conceptions of the conduction of heat: bringing together scientific and personal views, Physics Education, 20, 176-182.

Dilber, R., Karaman, I., & Duzgun, B. (2009). High School Students' Understanding of Projectile Motion Concepts. Educational Research and Evaluation, 15(3), 203-222.

Driver, R. (1989). Students' conceptions and the learning of science. International Journal of Science Education, 11, 481-490.

Duit, R., & Treagust, D. F. (2003). Conceptual Change: A Powerful Framework for Improving Science Teaching and Learning. International Journal of Science Education, 25(6), 671-688.

Erickson, G. L. (1979). Children's conceptions of heat and temperature. Science Education, 63, 221-230.

Erickson, G. L. (1980). Children's viewpoints of heat: A second look. Science Education, 64 (3), 323–36.

Erickson, G. L. & Tiberghien, A. (1985). Heat and Temperature. In R. Driver, E. Guesne, & A Tiberghien(Eds.), Children's ideas in science (pp. 52-83). Philadelphia, PA: Open University Press.

Eryılmaz, A. & Sürmeli, E. (2002). Measurement of Students' Misconceptions about Heat and Temperature with Three-Tier Test. 5th National Science and Mathematics Congress, Ankara.

Frederic, I., Valk, T., Lette, L. & Thoren, I. (1999). Pre-service physics teachers and conceptual difficulties on temperature and heat. European Journal of Teacher Education, 22, 61–74.

Gümüş, S., Öner, F., Kara, M., Orbay, M. & Yaman, S. (2003). Misconceptions about Heat and Temperature, Journal of National Education, 157.

Gürses, A. Doğar, Ç. & Yalçın, M. (2002). Examination of Investigation of Teaching Activity Based on Continuous Evaluation in Teaching of Heat and Temperature, 5th National Science and Mathematics Congress, Ankara.

Hameed, H., Hackling, M. W., & Garnett, P. J. (1993). Facilitating conceptual change in chemical equilibrium using a CAI strategy. International Journal of Science Education, 15, 221-230.

Harrison, A (1996). Student Difficulties in Differentiating Heat and Temperature. Paper presented in 21st Annual Conference of the Western Australian Science Education Association, Perth, November, 1996.

Harrison, A. G. & Treagust, D. F. (2001). Conceptual change using multiple interpretive perspectives: Two case studies in secondary school chemistry. Instructional Science, 29, 45-85.

Harrison, A. G., Grayson, D. J. & Treagust, D. F. (1999). Investigating a Grade 11 Student's Evolving Conceptions of Heat and Temperature, Journal of Research in Science Teaching, Vol:36, No:1, 55-87.

Hewson, P. W., & Hewson, M. G. (1981). Effect of Instruction Using Students' Prior Knowledge and Conceptual Change Strategies on Science Learning. Part II: Anaysis of Instruction. ERIC. Web: http://www.eric.ed.gov/PDFS/ED204129.pdf

Hewson, P. & Hewson, M. (1991). The Status of students' conceptions Research in Physics Learning: Theoretical Issues and Empirical Studies. Institute for Science Education at the University of Kiel. 59-73.

Hewson P. W. & Thorley, N. R. (1989). The conditions of conceptual change in the classroom. International Journal of Science Education, 11(5)

Holen, A. (2000). The PBL group: Self-reflections and feedback for improved learning and growth, Medical Teacher, 22(5), 485-488.

Jara-Guerrero, S. (1993). Misconceptions on Heat and Temperature. Proceedings of the Third International Seminar on Misconceptions and Educational Strategies in Science and Mathematics, Ithaca, NY.

Jones, M. G., Carter, G. & Rua, M. J. (2000). Exploring the Development of Conceptual Ecologies: Communities of Concepts Related to Convection and Heat, Journal of Research in Science Teaching, 37(2), 139-159.

Kalem, R., Tanel, Z. & Çallıca, H. (2002). A Curriculum Development Study on Temperature and Heat Topic Teaching in Secondary School Physics Course, 5th National Science and Mathematics Congress, Ankara.

Kesidou, S. & Duit, R. (1993). Students' Conceptions of the Second Law of Thermodynamics: An Interpretive Study. Journal of Research in Science Teaching, 30, 85-106.

Kolari, S. & Savander-Ranne, C. (2000). Will the Application of Constructivism Bring a Solution. to Today's Problems of Engineering Education? Global Journal of Engineering Education, 4(3), 275-280.

Krajcik, J. S. (1991). Developing students' understandings of chemical concepts. In The psychology of learning science, Glynn, S. H., Yeany, R. H. & Britton B. K. (Eds.) Hillsdale, NJ: Lawrence Erlbaum Associates.

Laburu, C. E. & Niaz, M. (2002). A Lakatosian Framework to Analyze Situations of Cognitive Conflict and Controversy in Students' Understanding of Heat Energy and Temperature, Journal of Science Education and Technology, Vol. 11, No. 3, September, 211-219.

Leite, L. (1999). Heat and Temperature: An analysis of how these concepts are dealt with in textbooks, European Journal of Science Education, 22(1), 75-88.

Lewis, E. L. & Linn, M. C. (1994). Heat, energy and temperature concepts of adolescents, adults and experts: Implications for curricular improvements, Journal Research in Science Teaching, 31, 657-677.

Linn, M. C. & Songer, N. B. (1988). Curriculum reformulation: Incorporating technology into science instruction. Paper presented at the annual meeting of the American Educational Research Association: Conceptual Models of Science Learning and Science Instruction Symposium, New Orleans, LA.

Linn, M. C. & Songer, N. B. (1991). Teaching thermodynamics to middle school students: What are appropriate cognitive demands? Journal of Research in Science Teaching, 28, 885–918.

Lohman, M.C. & Finkelstein, M. (2000). Designing groups in problem-based learning to promote problem-solving skill and self-directedness. Instructional Science, 28, 291-307.

Luera, G. R., Otto, C. A. & Zitzewitz, P. W. (2005). A conceptual change approach to teaching energy & thermodynamics to pre-service elementary teachers. Journal Physics Teacher Education Online, 2(4), 3-8.

Mäntylä, T. (2006). From Fragmented to Stuctured Knowledge in Physics Teacher Education. Unpublished Licentiate's thesis, University of Helsinki Department of Physical Sciences.

Markow, P. G. & Lonning, R. A. (1998). Usefulness of concept maps in college chemistry laboratories: Students' perceptions and effects on achievement. Journal Research Science Teaching, 35, 1015-1029.

Nakhleh, M. B. & Mitchell, R. C. (1993). Concept learning versus problem solving. Journal of Chemical Education, 70, 190-192.

Niaz, M. (2000). A Framework to understand students' differentiation between heat energy and temperature and its educational implication. Interchange, 31, 1–20.

Niaz, M. (2006). Can the Study of Thermochemistry Facilitate Students' Differentiation between Heat Energy and Temperature?, Journal of Science Education and Technology, Vol. 15, No. 3, October, 269-276.

Olgun, Ö. S. Ç. (2008). Study of the Concepts of Heat and Temperature in Fifth Grade Students with Concept Mapping, H. U. Journal of Education, 34, 54-62.

Osborne, R., & Freyberg, P. (1985). Learning in science: The implication of children's science. Auckland: Heinmann.

Paik, S. H., Cho, B. K. & Go, Y. M. (2007). Korean 4- to 11-Year-Old Student Conceptions of Heat and Temperature, Journal of Research in Science Teaching, 44(2), 284-302.

Posner, G. J., Strike, K. A., Hewson, P. W., & Gertzog, W. A. (1982). Accomodation of a Scientific Conception: Toward a Theory of Conceptual Change. Science Education, 66(2), 211-227.

Prpic, J. K. & Hadgraft, R. G. (2003). What is Problem-Based Learning? (From: Yaman, S. (2003) The Effects on the learning outputs of problem based learning in science education. Unpublished PhD Dissertation. Gazi University, Ankara).

Reiner, M., Slotta, J. D., Chi, M. T. H. & Resnick, L. B. (2000). Naive Physics Reasoning: A Commitment to Substance-Based Conceptions. Cognition and Instruction, 18(1), 1-34.

Rogan, J. H. (1988). The development of a conceptual framework of heat. Science Education, 72(1), 103–113.

Shayer, M. & Wylam, H. (1981). The development of the concepts of heat and temperature in 10-13 year olds. Journal of Research in Science Teaching, 18(5), 419–434.

Smith, J. P., diSessa, A. A. & Roschelle J. (1993). Misconceptions Reconceived: A Constructivist Analysis of Knowledge in Transition, The Journal of the Learning Science, 3(2), 115-163.

Sözbilir, M. (2003). A review of selected literature on students' misconceptions of heat and temperature, Boğaziçi University Journal of Education, 20, No.1: 25–41.

Streveler, R. A., Litzinger, T. A., Miller, R. L. & Steif, P. S. (2008). Learning Conceptual Knowledge in the Engineering Sciences: Overview and Future Research Directions. Journal of Engineering Education, July 2008, 279-294.

Streveler, R. A., Olds, B. M., Miller, R. L. & Nelson, M. A. (2003). Using a Delphi study to identity the most difficult concepts for students to master in thermal and transport science. In Proceedings, American Society for Engineering Education Annual Conference. Nashville, TN.

Şenocak, E., Dilber, R., Sözbilir, M. ve Taşkesenligil, Y. (2003). A study on the levels of primary school students' understanding of heat and temperature, Journal of Pamukkale University Education Faculty, 13, 199-210.

Taber, K. S. (2000). Finding the optimum level of simplification: the case of teaching about heat and temperature, Physics Education, 35(5) September, 320-325.

Tanahoung, C., Chitaree, R., Soankwan, C., Sharma, M. D. & Johnston, I. D. (2009). The effect of Interactive Lecture Demonstrations on students' understanding of heat and temperature: a study from Thailand, Research in Science & Technological Education, Vol. 27, No. 1, April 2009, 61–74.

Thomas, P. L. & Schwenz, R. W. (1998). College physical chemistry students' conceptions of equilibrium and fundamental thermodynamics, Journal of Research in Science Teaching, 35(10), 1151–1160.

Thomaz, M. F., Malaquias, I. M., Valente, M. C. & Antunes, M. J. (1995). An attempt to overcome alternative conceptions related to heat and temperature. Physics Education, 30, 19, Issue 1, January, 19-26.

Tiberghien, A. (1980). Modes and conditions of learning. An example: The learning of some aspects of the concepts of heat. In W. F. Archenhold, R. H. Driver, A. Orton, & C.Wood-Robinson (Eds.), Cognitive development research in science and mathematics (pp. 288–309). Leeds, England: University of Leeds.

Vosniadou, S. (1994). Capturing and Modeling the Process of Conceptual Change. Learning and Instruction, 4, 45-69.

Warren, J. W. (1972). The teaching of the concept of heat, Physics Education, 7, 41-44.

White, R. T. (1992). Implications of recent research on learning for curriculum and assessment. Journal of Curriculum Studies, 24, pp. 153-164.

Wiser, M. & Amin, T. (2001). "Is heat hot?" Inducing conceptual change by integrating everyday and scientific perspectives on thermal phenomena, Learning and Instruction, 11, 331–355.

Wiser, M., & Carey, S. (1983). When heat and temperature were one. In D. Gentner ve A.L. Stevens (Eds.), Mental models (pp. 99–129). Hillsdale, NJ: Erlbaum.

Yeo, S. & Zadnik, M. (2001). Introductory thermal concept evaluation: assessing students' understanding. The Physics Teacher, 39(8), 495–504.

Zacharia, Z. C., Olympiou, G. & Papaevripidou, M. (2008). Effects of Experimenting with Physical and Virtual Manipulatives on Student' Conceptual Understanding in Heat and Temperature, Journal of Research in Science Teaching, 45(9), 1021-1035.

 


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