Effect of Conceptual Change Oriented Instruction on Students’ Conceptual Understanding and Decreasing Their Misconceptions in DC Electric Circuits

Abstract

The purpose of this study was twofold: first to investigate the effect of conceptual change oriented instruction accompanied by concept cartoon worksheet with simulation on students’ conceptual understanding and second to remedy their misconceptions of direct current electric circuits. Participants were 139 pre-service science teachers from four intact classes. A quasi-experimental design was used in the study. The experimental group studied the concept with the application of concept cartoon worksheet and simulation, and the control group studied it with traditional instruction. Students’ conceptual understanding and misconceptions were measured by a tree-tired misconception test. It was administered as pre-and-posttest. There was no significant difference between the means of pre-test scores of experimental and control groups. The main effect of treatment on post-test scores was examined via ANCOVA with pre-test scores used as covariate. The frequency of each misconception was calculated for both groups, from pre to post-tests regarding all tiers of items. The analysis yielded a significant treatment effect on students’ post-test performances. The findings indicated that the conceptual change oriented instruction accompanied by concept cartoon worksheet and simulation is likely to be effective for conceptual understanding and decreasing most of students’ misconceptions in direct current electric circuits.

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Taşlıdere, E. (2013). Effect of Conceptual Change Oriented Instruction on Students’ Conceptual Understanding and Decreasing Their Misconceptions in DC Electric Circuits. Creative Education, 4, 273-282. doi: 10.4236/ce.2013.44041.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1] Atasoy, S. (2008). Researching effectiveness of worksheets developed to remedying students teachers’ misconceptions about Newton’s Laws of Motion. Unpublished Doctoral Dissertation, Trabzon: Karadeniz Technical University.
[2] Ate?, S., & Polat, M. (2005). The effects of learning cycle method on removing misconceptions related to electric circuits. Hacettepe University Journal of Education, 28, 39-47.
[3] Baka?, M., Ta?o?lu, A. K., & Akbay, T. (2011). The effect of computer assisted instruction with simulation in science and physics activities on the success of student: Electric current. Eurasion Journal of Physics and Chemistry Education, 1, 34-42.
[4] Baser, M. (2006). Effects of conceptual change and traditional confirmatory simulations on pre-service teachers’ understanding of direct current circuits. Journal of Science Education and Technology, 15, 367-381. doi:10.1007/s10956-006-9025-3
[5] Birisci, S., Metin, M., & Karakas, M. (2010). Pre-service elementary teachers’ views on concept cartoons: A sample from Turkey. Middle East Journal of Scientific Research, 5, 91-97.
[6] Bryan, J. A., & Slough, S. W. (2009). Converging lens simulation design and image predictions. Physics Education, 44, 264-275. doi:10.1088/0031-9120/44/3/006
[7] Bryce, T., & MacMillan, K. (2005). Encouraging conceptual change: The use of bridging analogies in the teaching of action-reaction forces and the ‘at rest’ condition in physics. International Journal of Science Education, 27, 737-763. doi:10.1080/09500690500038132
[8] Burhan, Y. (2008). Developing worksheets enriched by concept cartoons concerning the acid-base concepts. Unpublished Master Thesis, Trabzon: Karadeniz Technical University.
[9] Caleon, I., & Subramaniam, R. (2010). Development and application of a three-tier diagnostic test to assess secondary students’ understanding of waves. International Journal of Science Education, 32, 939 961. doi:10.1080/09500690902890130
[10] Cal1k, M., Okur, M., & Taylor, N. (2011). A comparison of different conceptual change pedagogies employed within the topic of “sound propagation”. Journal of Science Education and Technology, 20, 729-742. doi:10.1007/s10956-010-9266-z
[11] Celikten, O., Ertep1nar, H., & Geban, O. (2012). The effect of the conceptual change oriented instruction through cooperative learning on 4th grade students’ understanding of earth and sky concepts. Science Education International, 23, 84-96.
[12] 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. doi:10.1002/(SICI)1098-2736(199702)34:2<107::AID-TEA2>3.0.CO;2-X
[13] Chu, H.-E., Treagust, D. F., & Chandrasegaran, A. L. (2009). A stratified study of students’ understanding of basic optics concepts in different contexts using two-tier multiple-choice items. Research in Science & Technological Education, 27, 253-265. doi:10.1080/02635140903162553
[14] Clement, J. (1982). Students’ preconceptions in introductory mechanics. American Journal of Physics, 50, 66-71. doi:10.1119/1.12989
[15] Cohen, R., Eylon, B., & Ganiel, U. (1983). Potential difference and current in simple electric circuits: A study of student’s concepts. American Journal of Physics, 51, 407-412. doi:10.1119/1.13226
[16] Cox, A. J., Belloni, M., & Dancy, M. (2003). Teaching thermodynamics with Physlets? in introductory physics. Physics Education, 38, 433-440. doi:10.1088/0031-9120/38/5/309
[17] Dole, J. A., & Sinatra, G. M. (1998). Reconceptualizing change in the cognitive construction of knowledge. Educational Psychologist, 33, 109-128.
[18] Driver, R., & Erickson, G. (1983). Theories in action: Some theoretical and empirical issues in the study of students’ conceptual frameworks in science. Studies in Science Education, 10, 37-60. doi:10.1080/03057268308559904
[19] Dupin, J. J., & Johsua, S. (1987). Conceptions of French pupils concerning electric circuits: Structure and evolution. Journal of Research in Science Teaching, 24, 791-806. doi:10.1002/tea.3660240903
[20] Ekici, F., Ekici, E., & Ayd1n, F. (2007). Using concept cartoons in diagnosing and overcoming misconceptions related to photosynthesis. International Journal of Environmental & Science Education, 2, 111-124.
[21] Engelhardt, P. V., & Beichner, R. J. (2004). Students’ understanding of direct current resistive electrical circuits. American Journal of Physics, 72, 98-115. doi:10.1119/1.1614813
[22] Ery?lmaz, A. (2002). Effects of conceptual assignments and conceptual change discussions on students’ misconceptions and achievement regarding force and motion. Journal of Research in Science Teaching, 39, 1001-1015. doi:10.1002/tea.10054
[23] Fetherstonhaugh, T., & Treagust, F. D. (1992). Students’ understanding of light and its properties: Teaching to engender conceptual change. Science Education, 76, 653-672. doi:10.1002/sce.3730760606
[24] Gilbert, J. K., & Watts, D. M. (1983). Concepts, misconceptions and alternative conceptions: Changing perspectives in science education. Studies in Science Education, 10, 61-98. doi:10.1080/03057268308559905
[25] Gregoire, M. (2003). Is it a challenge or a threat? A dualprocess model of teachers’ cognition and appraisal process during conceptual change. Educational Psychology Review, 15, 147-179. doi:10.1023/A:1023477131081
[26] Gürses, E., Akdeniz, A. R., & Atasoy, ?. (2006). Durgun elektrik kon usunda 5E modeline g?re geli?tirilen materyallerin ??renci ba?arisina etkisi. 7th National Congress of Science and Mathematics Education, Ankara: Gazi University.
[27] Guzetti, B. J., Snyder, T. E., Glass, G. V., & Gamas, W. S. (1993). Promoting conceptual change in science: A comparative meta analysis of instructional interventions from reading education and science education. Reading Research Quarterly, 28, 116-159. doi:10.2307/747886
[28] Hammer, D. (1996). More than misconceptions: Multiple perspectives on student knowledge and reasoning, and an appropriate role for education research. American Journal of Physics, 64, 1316-1325. doi:10.1119/1.18376
[29] Hasan, S., Bagayoko, D., & Kelley, E. L. (1999). Misconceptions and the certainty of response index (CRI). Physics Education, 34, 294 299. doi:10.1088/0031-9120/34/5/304
[30] Heller, M., & Finley, F. N. (1992). Variable uses of alternative conceptions: A case study in current electricity. Journal of Research in Science Teaching, 29, 259-275. doi:10.1002/tea.3660290306
[31] Hewson, P. W. (1982). A case study of conceptual change in special relativity: The influence of prior knowledge in learning. European Journal of Science Education, 4, 61-78. doi:10.1080/0140528820040108
[32] Hynd, C., & Alvermann, D. E. (1986). The role of refutation text in overcoming difficulty with science concepts. Journal of Reading, 29, 440-446.
[33] Jaakkola, T., & Nurmi, S. (2008). Fostering elementary school students’ understanding of simple electricity by combining simulation and laboratory activities. Journal of Computer Assisted Learning, 24, 271-283. doi:10.1111/j.1365-2729.2007.00259.x
[34] Kabap1nar, F. (2009). What makes concept cartoons more effective? Using research to inform practice. Education and Science, 34, 104-118.
[35] Keogh, B., Naylor, S., & Wilson, C. (1998). Concept cartoons: A new perspective on physics education. Physics Education, 33, 219-224. doi:10.1088/0031-9120/33/4/009
[36] Keogh, B., & Naylor, S. (1999). Concept cartoons, teaching and learning in science: An evaluation. International Journal of Science Education, 21, 431-446. doi:10.1080/095006999290642
[37] Keogh, B., & Naylor, S. (2000). Teacher and learning in science using concept cartoons: Why Dennis wants to stay in at playtime. Australian Primary and Junior Science Journal, 16, 10-14.
[38] McDermott, L. C., & Shaffer, P. S. (1992). Research as a guide for curriculum development: An example from introductory electricity. Part I: Investigation of student understanding. American Journal of Physics, 60, 994-1003. doi:/10.1119/1.17003
[39] Mulhall, P., MCKittrick, B., & Gunstone, R. (2001). A perspective on the resolution of confusion in the teaching of electricity. Research in Science Education, 31, 575-587. doi:/10.1023/A:1013154125379
[40] Pallant, J. (2007). SPSS survival manual—A step by step guide to data analysis using SPSS for windows (3rd ed.). Maidenhead: Open University Press.
[41] Pesman, H., & Ery1lmaz, A. (2010). Development of a three-tier test to assess misconceptions about simple electric circuits. The Journal of Educational Research, 103, 208-222. doi:/10.1080/00220670903383002
[42] Piquette, J. S., & Heikkinen, H. W. (2005). Strategies reported used by instructors to address student alternate conceptions in chemical equilibrium. Journal of Research in Science Teaching, 42, 1112-1134. doi:/10.1002/tea.20091
[43] Posner, G., J., Srike, K. A., Hewson, P. W., & Gertzog, W. A. (1982). Accommodation of a scientific conception: Toward a theory of conceptual change. Science Education, 66, 211-227 doi:/10.1002/sce.3730660207
[44] Powell, C. K., & Kalina, J. C. (2009). Cognitive and social constructivism: Developing tools for an effective classroom. Education, 130, 241-250.
[45] Redish, E. F., Saul, J. M., & Steinberg R. N. (1998). Student expectations in introductory physics. American Journal of Physics, 66, 212-224. doi:/10.1119/1.18847
[46] Ronen, M., & Eliahu, M. (2000). Simulation—A bridge between theory and reality: The case of electric circuits. Journal of Computer Assisted Learning, 16, 14-26. doi:/10.1046/j.1365-2729.2000.00112.x
[47] Roth, K. J. (1985). Conceptual change learning and student processing of science texts. Paper presented at the annual meeting of American Research Association, Chicago, April 1985, 46 p.
[48] Sencar, S., & Ery1lmaz, A. (2004). Factors mediating the effect of gender on ninth-grade Turkish students’ misconceptions concerning electric circuit. Journal of Research in Science Teaching, 41, 603-616. doi:/10.1002/tea.20016
[49] Shipstone, D. (1988). Pupils’ understanding of simple electrical circuits. Physics Education, 23, 92-96. doi:/10.1088/0031-9120/23/2/004
[50] Shipstone, D. M., von Rh?neck, C., Jung, W., K?rrqvist, C., Dupin, J. J., Joshua, S., & Licht, P. (1988). A study of students’ understanding of electricity in five European countries. International Journal of Science Education, 10, 303-316. doi:/10.1080/0950069880100306
[51] Smit, E. L., Blakeslee, T. D., & Anderson, C. W. (1993). Teaching strategies associated with conceptual change learning in science. Journal of Research in Science Teaching, 30, 111-126. doi:/10.1002/tea.3660300202
[52] Stephenson, P., & Warwick, P. (2002). Using concept cartoons to support progression in students’ understanding of light. Physics Education, 37, 135-141. doi:/10.1088/0031-9120/37/2/306
[53] Taber, S. K., Trafford, T., & Quail, T. (2006). Conceptual resources for constructing the concepts of electricity: The role of models, analogies and imagination. Physics Education, 41, 155-160. doi:/10.1088/0031-9120/41/2/006
[54] Tasl1dere, E. (2103). The effect of concept cartoon worksheets on students’ conceptual understandings of geometrical optics. Education and Science, 38, 144-161.
[55] Treagust, D. F., & Duit, R. (2008). Conceptual change: A discussion of theoretical, methodological and practical challenges for science education. Cultural Studies of Science Education, 3, 297-328. doi:/10.1007/s11422-008-9090-4
[56] Vosniadou, S. (2007). Conceptual Change and Education. Human Development, 50, 47-54. doi:/10.1159/000097684
[57] Zacharia, Z. C. (2005). The impact of interactive computer simulations on the nature and quality of post graduate science teachers’ explanations in physics. International Journal of Science Education, 27, 1741-1767. doi:/10.1080/09500690500239664
[58] Zhou, G. (2010). Conceptual change in science: A process of argumentation. Eurasia Journal of Mathematics, Science & Technology Education, 6, 101-110.

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