Asia-Pacific Forum on Science Learning and Teaching, Volume 10, Issue 2, Article 5 (Dec., 2009)
Gökhan DEMİRCİOĞLU
Comparison of the effects of conceptual change texts implemented after and before instruction on secondary school students’ understanding of acid-base concepts

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References

Ayas, A., & Demircioğlu, G. (2002). Student teachers. understanding and misconceptions of acids, bases and salts in chemistry, First International Education Conference, Changing times, Changing Needs, Eastern Mediterranean University, May 8-10, 2002, Gazimagusa, North Cyprus.

Ayvacı, H. Ş. Devecioğlu, Y. (2009, 1-3 May). The new educational program and the innovational viewpoints of teachers, The first international congress of educational research, The association of educational research community, Çanakkale,Turkey,Retrieved december 4, 2009, from http://oc.eab.org.tr/egtconf/pdfkitap/pdf/458.pdf.

Basili, PA. & Sanford, JP. (1991). Conceptual change strategies and cooperative group work in chemistry. Journal of Research in Science Teaching, 28, 293-304.

Başer, M. & Geban, Ö. (2007). Effectiveness of conceptual change instruction on understanding of heat and temperature concepts, Research in Science & Technological Education, 25(1), 115–133.

Bradley, J.D. & Mosimege, M.D. (1998). Alternative conceptions in acids and bases: A comparative study of student teachers with different chemistry backgrounds. South African Journal of Chemistry, 51, 137-150.

Çakan, M. (2004). Öğretmenlerin Ölçme-Değerlendirme Uygulamaları ve Yeterlik Düzeyleri: İlk ve Ortaöğretim (In Turkish), Ankara Üniversitesi Eğitim Bilimleri Fakültesi Dergisi, 37, 99–114.

Çakır, Ö. Uzuntiryaki, E., & Geban, O. (2002).Contribution of conceptual change texts and concept mapping to students’ understanding of acids and bases. Paper presented at the Annual Meeting of the National Association for Research in Science Teaching, April 6-10, 2002, New Orleans, LA.

Çakır, İ. & Çimer, S.O. (2007, 15-17 Nov.). Fen ve Teknoloji Öğretmenlerinin Alternatif Ölçme Değerlendirme Konusundaki Yeterlilikleri ve Uygulamada Karşılaşılan Problemler. I. Ulusal İlköğretim Kongresi. Ankara.

Canpolat, N., Pınarbaşı, T., Bayrakçeken, S. & Geban, O. (2006). The conceptual change approach to teaching chemical equilibrium. Research in Science & Technological Education, 24(2), 217-235.

Chambers, S.K., & Andre, T. (1997). Gender, prior knowledge, interest, and experience in electricity and conceptual change text manipulations in learning about direct current. Journal of Research in Science Teaching, 34, 107-123.

Champagne, A.B, Gunstone, R.F., & Klopfer, L.E. (1983).Naive knowledge and science learning. Research in Science and Technological Education, 1, 173-183.

Christianson, R.G. & Fisher, K.M. (1999). Comparison of student learning about diffusion and osmosis in constructivist and traditional classroom. International Journal of Science Education, 21, 689-698.

Cros, D., Maurin, M., Amouroux, R., Chastrette, M., Leber J., & Fayol M. (1986). Conceptions of first-year university students of the constituents of matter and the notions of acids and bases. European Journal of Science Education, 8, 305-313.

Cros, D., Chastrette, M., & Fayol, M. (1988). Conceptions of second year university students of some fundamental notions in chemistry. International Journal of Science Education, 10, 331-336.

Demerouti, M., Kousathana, M., & Tsaparlis, G. (2004). Acid-base equilibria, Part I. Upper secondary students’ alternative conceptions and difficulties. The Chemical Educator, 9, 122-131.

Demircioğlu G. (2003). Developing and implementing teacher guide material related to the unit “acids and bases” at 10th grade level. PhD Thesis, Graduate school of natural and applied sciences, Karadeniz Technical University, Trabzon.

Demircioğlu, G., Özmen, H. & Ayas, A. (2004). Asit ve baz kavramları üzerine bir araştırma çerçevesinde kimyada karşılaşılan kavram yanılgıları (In Turkish). Educational Sciences: Theory & Practice, 4(1), 73-80.

Demircioğlu, G., Ayas, A., & Demircioğlu, H. (2005). Conceptual change achieved through a new teaching program on acids and bases. Chemistry Education Research and Practice, 6, 36-51.

Diakidoy, I.-A.N., Kendeou, P., & Ioannides, C. (2003). Reading about energy: The effects of text structure in science learning and conceptual change. Contemporary Educational Psychology, 28(3), 335-356.

Driver, R., & Easley, J. (1978). Pupils and paradigms: A review of literature related to concept development in adolescent science students. Studies in Science Education, 5, 61-84.

Duit, R., Treagust, D., & Widodo, A. (2008). Teaching science for conceptual change—Theory and practice. In S. Vosniadou, et al. (Eds.), International handbook of research on conceptual change (pp. 629–646). New York: Routledge.

Ebenezer, J.V. & Gaskell, P.J. (1995). Rational conceptual change in solution chemistry. Science Education, 79, 1-17.

Guba, E. G., & Lincoln, Y. S. (1994). Competing paradigms in qualitative research, cited in: Denzin, N.K & Lincoln, Y.S, Handbook of Qualitative Research, Sage:105-17.

Guzzetti, B. J., Hynd, C. R., Skeels, S. A., & Williams, W. O. (1995). Improving high school physics texts: Students speak out. Journal of Reading, 36, 656–663.

Guzzetti, B. J. (2000). Learning counter intuitive science concepts: What have we learned from over a decade of research? Reading, Writing, Quarterly, 16, 89-98.

Guzzetti, B.J., Williams, W.O., Skeels, S.A., & Wu, S.M. (1997). Influence of text structure on learning counterintuitive physics concepts. Journal of Research in Science Teaching, 34, 701-719.

Hand, B., & Treagust, D.F. (1991). Student achievement and science curriculum development using a constructivist framework. School Science and Mathematics, 91, 172-176.

Hewson, PW. (1981). A conceptual change approach to learning science. European Journal of Science Education, 3, 383-396.

Hewson, P.W. & Hewson, M.G. (1984). The role of conceptual conflict in conceptual change and the design of science education. Instructional Science, 13, 1-13.

Horton, P.B., McConnly, A.A., Gallo, M., Woods, A.I., Senn, G.J. & Hamelin, D. (1993). An investigation of the effectiveness of concept mapping as an instructional tool. Science Education, 77(1), 95–111

Hynd, C. R., McWhorter, I. Y., Phares, V. L., & Suttles, C. W. (1994). The role ofinstmctional variables in conceptual change in high school physics topics. Journal of Research in Science Teaching, 31(9), 933-946.

Hynd, C.R., Alvermann, D., & Qian, G. (1997). Pre-service elementary school teachers’ conceptual change about projectile motion: Refutation text, demonstration, affective factors, and relevance. Science Education, 81, 1–27.

Jonassen, J. H., & Grabowski, B. L. (1993). Handbook of Individual Differences, learning and instruction. Part VII, Prior knowledge. Hillsdale: Lawrence Erlbaum Associates.

Mason, L. (1998). Sharing cognition to construct scientific knowledge in school context: the role of oral and written discourse. Instructional Science, 26(5), 359–389.

Mason, L. & Santi, M. (1998). Discussing the greenhouse effect: children’s collaborative discourse reasoning and conceptual change. Environmental Education Research, 4(1),67-85

Mellado, V. (1997). Preservice teachers’ classroom practice and their conceptions of the nature of science. Science and Education, 6, 331-354.

Nakhleh, MB. (1992). Why some students don’t learn chemistry, Journal of Chemical Education, 69, 191–196.

Nakhleh, M.B., & Krajcik, J.S. (1993). A protocol analysis of the influence of technology on students. actions, verbal commentary, and thought processes during the performance of acid-base titrations. Journal of Research in Science Teaching, 30, 1149-1168.

Nakhleh, M.B., & Krajcik, J.S. (1994). Influence of levels of information as presented by different technologies on students. Understanding of acid, base, and pH concepts. Journal of Research in Science Teaching, 34, 1077-1096.

Niaz, M., Aguilera, D., Maza, A., & Liendo, G. (2002). Arguments, contradictions, resistances and conceptual change in students’ understanding of atomic structure. Science Education, 86, 505-525.

Okebukola, P. A.(1990). Attaining meaningful learning of concepts in genetics and ecology: An examination of thepotency of the concept mapping technique. Journal of Research in Science Teaching, 27(5), 493-504.

Özmen, H. (2007). The effectiveness of conceptual change texts in remediating high school students’ alternative conceptions concerning chemical equilibrium. Asia Pacific Education Review, 8(3), 413-425.

Özmen, H., Demircioğlu, G., & Coll, R. (2009). A comparative study of the effects of a concept mapping enhanced laboratory experience on Turkish high school students’ understanding of acid-base chemistry. International Journal of Science and Mathematics Education, 7, 1-24.

Özmen, H., Demircioğlu, H. & Demircioğlu, G. (2009). The effects of conceptual change texts accompanied with animations on overcoming 11th grade students’ alternative conceptions of chemical bonding, Computers & Education, 52, 681-695.

Özmen, H. and Yıldırım, N. (2005). Effect of work sheets on student's success: Acids and bases sample, Journal of Turkish science education, 2(2), 64-67.

Pabuçcu, A. & Geban, Ö. (2006). Remediating misconceptions concerning chemical bonding through conceptual change text, Hacettepe University Journal of Education. 30, 184-192.

Palmer, D. (1999). Exploring the link between students’ scientific and nonscientific conceptions. Science Education, 83, 639-653.

Pardhan, H., & Bano, Y. (2001). Science teachers' alternate conceptions about direct currents. International Journal of Science Education, 23(3), 301-318.

Peterson, RF, Treagust, DF., & Garnett, P. (1986). Identification of secondary student’s alternative conceptions of covalent bonding and structure concepts using a diagnostic test instrument. Research in Science Education, 16, 40-48.

  Pfundt, H & Duit, R. (1991). Bibliography of students’ alternative frameworks in science education, (Kiel, Germany:IPN).

Pintrich, P.R., Marx, R.W. & Boyle, R.W. (1993). Beyond cold conceptual change: The role of motivational beliefs and classroom contextual factors in the process of conceptual change. Review of Educational Research, 63, 167-199.

Pınarbaşı, T. (2007). Turkish undergraduate students’ misconceptions on acids and bases. Journal of Baltic Science Education, 6(1), 23-34.

Posner, G.J, Strike, K.A, Hewson, P.W., & Gertzog, W.A. (1982). Accommodation of a scientific conception: toward of conceptual change. Science Education, 66, 211-227.

Qian, G., & Alvermann, D. (1995). Role of epistemological beliefs and learned helplessness in secondary school students’ learning science concepts from text. Journal of Educational Psychology, 87, 282–292.

Robson, C. (1998). Real Word Research, Blackwell Publishers Ltd., Oxford, UK.

Ross, B., & Munby, H. (1991). Concept mapping and alternative conceptions: A study of high school students’ understanding of acids and bases. International Journal of Science Education, 13, 11-23.

Roth, K. J. (1985) Conceptual change learning and students processing of science texts, paper presented at the Annual meeting of the American Education Research Association, Chicago, IL.

Saljo, R. (1999). Learning as the use of tools: A sociocultural perspective on the human-technology link. In K. Littleton & P. Light (Eds.), Learning with computers: Analysing productive interaction. London, New York: Routledge.

Schmidt, H.J. (1991). A label as a hidden persuader: chemists. Neutralization concept. International Journal of Science Education, 13, 459-471.

Sheppard, K. (2006). High school students’ understanding of titrations and related acid-base phenomena, Chemistry Education Research and Practice,7(1), 32-45.

Sinatra, G.M. & Pintrich, P.R. (2003). Intentional conceptual change. Mahwah, NJ: Erlbaum.

Sisovic, D., & Bojovic, S. (2000). Approaching the concepts of acids and bases by cooperative learning. Chemistry Education: Research and Practice in Europe, 1, 263-275.

Skopeliti, I., & Vosniadou, S. (2006). The Influence of Refutational Text on Children's Ideas about the Earth. Poster submitted for publication in the Proceedings of the 28th Annual Conference of the Cognitive Society, Vancouver, BC Canada.

Sungur, S., Tekkaya, C., & Geban, Ö. (2001). The contribution of conceptual change texts accompanied by concept mapping to students' understanding of the human circulatory system. School Science and Mathematics, 101(2), 91-101.

Tobin, K., Tippins, D.J., & Gallard, A.J. (1994). Research on instructional strategies for teaching science. In Gabel, D.L. (Ed.), Handbook of Research on Science Teaching and Learning (pp. 45-93). New York: Macmillan.

Toplis, R. (1998). Ideas about acids and bases. School Science Review, 80, 67-70.

Treagust, DF. (1988). Development and use of diagnostic tests to evaluate students’ alternative conceptions in science. International Journal of Science Education, 10, 159-169.

Treagust, D. & Duit, R. (2008). Compatibility betwen cultural studies and conceptual change in science education: there is more to aknowledge than to fight straw men!. Cultural Studies of Science Education, 3, 387–395.

Trend, R. (2001). Deep time framework: A preliminary study of UK primary teachers’ conceptions of geological time and perceptions of geoscience. Journal of Research in Science Teaching, 38(2), 191-221.

Vosniadou, S., Ioannides, C., Dimitrakopoulou, A., & Papademetriou, E. (2001). Designing learning environments to promote conceptual change in science. Learning and Instruction, 11, 381–419.

Vosniadou, S. (2007). Re-framingtheconceptualchangeapproachand itsre-framing, InVosniadou, S, Baltas, A & Vamvakoussi, X. Re-framing the Conceptual Change Approach in Learning and Instruction (p. 2). Oxford: Elsevier.

Vosniadou, S. (2008). Bridging culture with cognition: A commentary on ‘‘culturing conceptions: from first principles’’. Cultural Studies of Science Education, 3, 277–282.

Vosniadou, S. (2008a). Conceptual Change research: An introduction, In Vosniadou, S. (Ed.), Internetional handbook of research on conceptual change (p. XIX). Routhledge: New York and London.

Wang, T., & Andre, T. (1991). Conceptual change text versus traditional text and application questions versus no questions in learning about electricity. Contemporary Educational Psychology, 16, 103-116.

 


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