Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2020, , 440 - 463, 05.06.2020
https://doi.org/10.14686/buefad.643630

Öz

Kaynakça

  • Albanese, M. (2000). Problem-based learning: Why curricula are likely to show little effect on knowledge and clinical skills. Medical Education, 34, 729-738.
  • Albanese, M.A. & Mitchell, S. (1993). Problem-based learning: a review of literature on its outcomes and implementation issues. Academic Medicine, 68, 52–81.
  • Ali, R., Hukamdad, Akhter, A., & Khan, A. (2010). Effect of using problem solving method in teaching mathematics on the achievement of mathematics students. Asian Social Science, 6 (2), 67-72.
  • Allen, D. E., Duch, B. J., & Groh, S. E. (1996). The power of problem‐based learning in teaching introductory science courses. New directions for teaching and learning, 1996(68), 43-52.
  • Atkins, P., & Jones, L. (2009). Chemical principles. Macmillan.
  • Ayyıldız, Y., & Tarhan, L. (2013). Case study applications in chemistry lesson: gases, liquids, and solids. Chemistry Education Research and Practice, 14(4), 408-420.
  • Bağ, H., & Çalık, M. (2017). A Thematic Review of Argumentation Studies at the K-8 Level. Education & Science, 42(190).
  • Banta, T. W., Black, K. E., & Kline, K. A. (2000). PBL 2000 plenary address offers evidence for and against problem-based learning, PBL Insight to solve, to learn, together. A newsletter for undergraduate Problem Based Learning from Stamford, 3 (3).
  • Barret, T. & Naughton, C. (2015) Problem-based learning: an integrative approach to the cultivation of person-centeredness, empathy, and compassion.
  • Barrows, H. S., & Myers, A. C. (1993). Problem-based learning in secondary schools. Unpublished monograph. Springfield, IL: Problem-Based Learning Institute, Lanphier High School and Southern Illinois University Medical School.
  • Barrows, H. S., & Tamblyn, R. M. (1980). Problem-based learning: An approach to medical education. Springer Publishing Company.
  • Belland, B. R. (2010). Portraits of middle school students constructing evidence-based arguments during problem-based learning: The impact of computer-based scaffolds. Educational technology research and Development 58(3), 285-309.
  • Belland, B. R., Glazewski, K. D., & Richardson, J. C. (2011). Problem-based learning and argumentation: Testing a scaffolding framework to support middle school students’ creation of evidence-based arguments. Instructional Science, 39(5), 667-694.
  • Boud, D., & Feletti, G. (2013). The challenge of problem-based learning. Routledge.
  • Bouwma‐Gearhart, J., Stewart, J., & Brown, K. (2009). Student misapplication of a gas‐like model to explain particle movement in heated solids: implications for curriculum and instruction towards students’ creation and revision of accurate explanatory models. International Journal of Science Education, 31(9), 1157-1174.
  • Camp, G. (1996). Problem-based learning: A paradigm shifts or a passing fad? Medical Education Online, 1(1), 4282.
  • Cassel, D. G. (2002). Synergistic argumentation in a problem-centered learning environment. Doctoral dissertation, The University of Oklahoma, Oklahoma
  • Chin, C., & Chia, L. G. (2004). Problem‐based learning: Using students' questions to drive knowledge construction. Science Education, 88 (5), 707-727.
  • Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd ed.). Hillsdale, NJ: Erlbaum.
  • Creswell, J. W. (2002). Educational research: Planning, conducting, and evaluating quantitative (pp. 146-166). Upper Saddle River, NJ: Prentice Hall.
  • Çelik, A. Y., & Kılıç, Z. (2014). The impact of argumentation on high school chemistry students’ conceptual understanding, attitude towards chemistry and argumentativeness. Eurasian Journal of Physics and Chemistry Education, 6(1).
  • Dahlgren, M. A., Castensson, R., & Dahlgren, L. O. (1998). PBL from the teachers' perspective. Higher Education, 36 (4), 437-447.
  • Dobbs, V. (2008). Comparing Student Achievement in The Problem-Based Learning Classroom and Traditional Teaching Methods Classroom. ProQuest Information and Learning.
  • Dochy, F., Segers, M., Van den Bossche, P. & Gijbels, D. (2003). Effects of problem-based Learning: a meta-analysis. Learning and Instruction, 13 (5), 533–568.
  • Donnel, C. M., O’Connor, C. and Seery, M. K. (2007). Developing practical chemistry skills by means of student-driven problem-based learning mini-projects. Chemistry Education Research and Practice, 8 (2), 130-139.
  • Driver, R., Asoko, H., Leach, J., Scott, P., & Mortimer, E. (1994). Constructing scientific knowledge in the classroom. Educational researcher, 23(7), 5-12.
  • Driver, R., Newton, P., & Osborne, J. (2000). Establishing the norms of scientific argumentation in classrooms. Science education, 84 (3), 287-312.
  • Duch, B. J., Groh, S. E. & Allen, D. E. (2001). The power of problem-based learning. Stylus Publishing. Virginia (USA).
  • Duschl, R. A., & Osborne, J. (2002). Supporting and promoting argumentation discourse in science education. Studies in Science Education, 38(1), 39-72).
  • Erduran, S., & Jiménez-Aleixandre, M. P. (2008). Argumentation in science education. Perspectives from Classroom-Based Research. Dordre-cht: Springer.
  • Erduran, S., & Mugaloglu, E. Z. (2013). Interactions of economics of science and science education: Investigating the implications for science teaching and learning. Science & Education, 22(10), 2405-2425.
  • Erduran, S., & Pabuccu, A. (2012). Bonding chemistry and argument: teaching and learning argumentation through chemistry stories. Bristol: University of Bristol.
  • Etherington, M.B. (2011) Investigative primary science: A problem-based learning approach, Australian Journal of Teacher Education, Vol. 36, Issue 9, pp 53-74).
  • Ford, M. (2008). Disciplinary authority and accountability in scientific practice and learning. Science Education, 92 (3), 404-423.
  • Garnett, P.J. & Treagust, D.F. (1992). Conceptual difficulties experienced by senior high school students of chemistry: electrochemical (galvanic) and electrolytic cells, Journal of Research in Science Teaching, 29, 10, 1079-1099.
  • Gultepe, N., & Kilic, Z. (2015). Effect of scientific argumentation on the development of scientific process skills in the context of teaching chemistry. International Journal of Environmental and Science Education, 10(1), 111-132.
  • Greenwood J. D. (1999). Understanding the “Cognitive Revolution” in Psychology. Journal of the History of the Behavioral Sciences, 35(1), 1-22).
  • Groh, S. E. (2001). Using problem-based learning in general chemistry. (Eds.: Allen Deborah E.). The Power of Problem-Based Learning: A Practical "how to" for Teaching Undergraduate Courses in Any discipline (pp. 207).
  • Hefter, M. H., Berthold, K., Renkl, A., Riess, W., Schmid, S., & Fries, S. (2014). Effects of a training intervention to foster argumentation skills while processing conflicting scientific positions. Instructional Science, 42, 929-947.
  • Hmelo-Silver, C. E. (2004). Problem-based learning: What and how do students learn? Educational psychology review, 16(3), 235-266.
  • Hmelo-Silver, C. E., & Barrows, H. S. (2008). Facilitating collaborative knowledge building. Cognition and instruction, 26(1), 48-94.
  • Hmelo S. & Cindy E. (2004) Problem-Based Learning: What and How do students learn? Educational Psychology Review. 2004; 16:235-66;
  • Jiménez‐Aleixandre, M. P., Bugallo Rodríguez, A., & Duschl, R. A. (2000). “Doing the lesson” or “doing science”: Argument in high school genetics. Science Education, 84(6), 757-792.
  • Jiménez-Aleixandre, M. P., & Pereiro-Muñoz, C. (2005). Argument construction and change while working on a real environment problem. In Research and the quality of science education (pp. 419-431). Springer, Dordrecht.
  • Joung, S. (2003). The effects of high-structure cooperative versus low-structure collaborative design on online debate in terms of decision making, critical thinking, and interaction pattern. Doctoral Dissertation, The Florida State University, Florida.
  • Jonassen, D. H. (2011). Design Problems for Secondary Students. National Center for Engineering and Technology Education.
  • Ju, H., & Choi, I. (2018). The Role of Argumentation in Hypothetico-Deductive Reasoning During Problem-Based Learning in Medical Education: A Conceptual Framework. Interdisciplinary Journal of Problem-Based Learning, 12(1), 4.
  • Kelly, O., & Finlayson, O. (2009). A hurdle too high? Students’ experience of a PBL laboratory module. Chemistry Education Research and Practice, 10(1), 42-52.
  • Larive, C. K. (2004). Problem-based learning in the analytical chemistry laboratory course. Analytical and Bioanalytical Chemistry, 380 (3), 357-359.
  • Mann, M., Treagust, D. F. (1998). A pencil and paper instrument to diagnose students’ conception of breathing, gas exchange and respiration, Australian Science Teachers Journal, 44, 2, 55-59.
  • Marklin Reynolds, J., & Hancock, D. R. (2010). Problem‐based learning in a higher education environmental biotechnology course. Innovations in Education and Teaching International, 47 (2), 175-186.
  • McDonald, J.T., 2002. Using problem-based learning in a science methods course. Proceedings of the Annual International Conference of the Association for the Education of Teachers in Science, ERİC ED 465 621, Charlotte.
  • McGhee, M. (2015). The effects of argumentation scaffolding in a problem-based learning course on problem-solving outcomes and learner motivation. Doctoral Dissertation, The Florida State University.
  • Mehalik, M. M., Doppelt, Y., & Schuun, C. D. (2008). Middle‐school science through design‐based learning versus scripted inquiry: Better overall science concept learning and equity gap reduction. Journal of Engineering Education, 97(1), 71-85.
  • Noh, T., & Scharmann, L. C. (1997). Instructional influence of a molecular‐level pictorial presentation of matter on students' conceptions and problem‐solving ability. Journal of Research in Science Teaching: The Official Journal of the National Association for Research in Science Teaching, 34(2), 199-217.
  • Nussbaum, E. M., & Edwards, O. V. (2011). Critical questions and argument stratagems: A framework for enhancing and analyzing students’ reasoning practices. The Journal of the Learning Sciences, 1-46.
  • Osborne, J., Erduran, S. & Simon, S. (2004). Enhancing the quality of argumentation in school science. Journal of Research in Science Teaching, 41 (10), 994-1020.
  • Osborne, J., Erduran, S., Simon, S., & Monk, M. (2001). Enhancing the quality of argument in school science. School science review, 82(301), 63-70.
  • Özmen, H. (2011). Effect of animation enhanced conceptual change texts on 6th grade students’ understanding of the particulate nature of matter and transformation during phase changes. Computers & Education, 57(1), 1114-1126.
  • Papastergiou, M. (2009). Digital game-based learning in high school computer science education: Impact on educational effectiveness and student motivation. Computers & Education, 52(1), 1-12.
  • Pepper, C. (2010). ‘There’s a lot of learning going on but NOT much teaching!’: student perceptions of problem‐based learning in science. Higher Education Research & Development, 29 (6), 693-707.
  • Peterson, R. F. & Treagust, D. F. (1998). Learning to teach primary science through problem-based learning. Science Education, 82 (2), 215-237.
  • Ramstedt, M., Hedlund, T., Björn, E., Fick, J., & Jahnke, I. (2016). Rethinking chemistry in higher education towards technology enhanced problem-based learning. Education Inquiry, 7 (2).
  • Ronis, D. L. (2007). Problem-based learning for math & science: Integrating inquiry and the internet. Corwin.
  • Sağır, Ş. U., & Kılıç, Z. (2012). Analysis of the Contribution of Argumentation-Based Science Teaching on Student Success and Retention. Eurasian Journal of Physics & Chemistry Education, 4(2).
  • Savery, J. R. (2006). Overview of problem-based learning: Definitions and distinctions. Interdisciplinary Journal of Problem-based Learning, 1(1), 3.
  • Schwartz, P., Webb, G., & Mennin, S. (Eds.). (2001). Problem-based learning: Case studies, experience and practice. Psychology Press.
  • Skamp, K. (1999). Are Atoms and Molecules Too Difficult for Primary Children? School Science Review, 81(295), 87-96.
  • Torp, L. & Sage, S. (2002). Problem as Possibilities: Problem-Based Learning for K-16 Education. Alexandria, VA, USA: Association for Supervision and Curriculum Development.
  • Treagust, D. F. (1988). Development and use of diagnostic tests to evaluate students’ misconceptions in science. International journal of science education, 10(2), 159-169.
  • Tüysüz, C., Demirel, O. E., & Yildirim, B. (2013). Investigating the effects of argumentation, problem and laboratory-based instruction approaches on pre-service teachers’ achievement concerning the concept of “acid and base”. Procedia-Social and Behavioral Sciences, 93, 1376-1381.
  • Velez, A. B. (2008). Thinking critically together: The intellectual and discursive of controversial conversations. Doctoral Dissertation, The Harvard University, Massachusetts.
  • Vernon, D. T., & Blake, R. L. (1993). Does problem-based learning work? A meta-analysis of evaluative research. Academic medicine, 68 (7), 550-63.
  • Voska, K. W., Heikkinen, H. W. (2000). Identification and analysis of student conception used to solve chemical equilibrium problems, Journal of Research in Science Teaching, 37, 2, 160-176.
  • Walton, D. (2007). Media argumentation: dialectic, persuasion and rhetoric. Cambridge University Press.
  • West, T. L. (1994). The effect of argumentation instruction on critical thinking skills. Doctoral Dissertation. Southern Illinois University, Chicago.
  • Wood, D.F. (2003). Problem based learning, ABC of learning and teaching in medicine, 326 (7384): 328-330
  • Yuzhi, W. (2003). Using problem-based learning in teaching analytical chemistry. The China Papers, 2, 28-33.

The Effect of Argumentation-supported Problem Based Learning on the Achievements of Science Teacher Candidates Regarding the Subjects of Gases and Acids-Bases

Yıl 2020, , 440 - 463, 05.06.2020
https://doi.org/10.14686/buefad.643630

Öz

Important criticisms of classes where problem-based
learning (PBL) has been applied as an educational approach include situations
in which students only learn part of a subject; in other words, they miss
important information and do not learn the subject completely. There is much
research in the literature showing that in classes where the argumentation
method is applied, the conceptual learning of students develops significantly.
In this study, our aim was to investigate whether the missing element in the
PBL method could be supplied by supporting the PBL method with argumentation during
a class on the topic of acidity/alkalinity and gases. In the research, a
non-equivalent (pre-test and post-test) control-group design was used. The research sample was composed of 140 science
teacher candidates at three different branches within the context of scientific
laboratory applications lessons in the third year at a state university in
Turkey. The study was carried out with two experimental groups and one control
group. In one of the experimental groups, problem based learning (PBL) was
applied (N=44), and, in the other experimental group, argumentation-supported problem
based learning (AS-PBL) was applied (N=46. In the control group, a traditional teaching
approach (TTA) was carried out. The study was eight weeks in duration (N=50).
Data was collected through a) the acids/bases academic achievement test and b) the
gases academic achievement test and were analyzed by t-test and ANOVA (analysis
of variance). The results revealed that the academic achievement of the
students in the experiment group where teaching method AS-PBL was applied
regarding acids/bases and gases were higher than the academic achievement of the
students in the other experimental group at a significant level. The academic
achievement of students in the group where the PBL method
was applied was even lower than the academic achievement of students in the control
group. This situation was an indication that the starting point of the research
was correct. In this study, by completing the missing part of the PBL, the use
of argumentation increased
achievement.

Kaynakça

  • Albanese, M. (2000). Problem-based learning: Why curricula are likely to show little effect on knowledge and clinical skills. Medical Education, 34, 729-738.
  • Albanese, M.A. & Mitchell, S. (1993). Problem-based learning: a review of literature on its outcomes and implementation issues. Academic Medicine, 68, 52–81.
  • Ali, R., Hukamdad, Akhter, A., & Khan, A. (2010). Effect of using problem solving method in teaching mathematics on the achievement of mathematics students. Asian Social Science, 6 (2), 67-72.
  • Allen, D. E., Duch, B. J., & Groh, S. E. (1996). The power of problem‐based learning in teaching introductory science courses. New directions for teaching and learning, 1996(68), 43-52.
  • Atkins, P., & Jones, L. (2009). Chemical principles. Macmillan.
  • Ayyıldız, Y., & Tarhan, L. (2013). Case study applications in chemistry lesson: gases, liquids, and solids. Chemistry Education Research and Practice, 14(4), 408-420.
  • Bağ, H., & Çalık, M. (2017). A Thematic Review of Argumentation Studies at the K-8 Level. Education & Science, 42(190).
  • Banta, T. W., Black, K. E., & Kline, K. A. (2000). PBL 2000 plenary address offers evidence for and against problem-based learning, PBL Insight to solve, to learn, together. A newsletter for undergraduate Problem Based Learning from Stamford, 3 (3).
  • Barret, T. & Naughton, C. (2015) Problem-based learning: an integrative approach to the cultivation of person-centeredness, empathy, and compassion.
  • Barrows, H. S., & Myers, A. C. (1993). Problem-based learning in secondary schools. Unpublished monograph. Springfield, IL: Problem-Based Learning Institute, Lanphier High School and Southern Illinois University Medical School.
  • Barrows, H. S., & Tamblyn, R. M. (1980). Problem-based learning: An approach to medical education. Springer Publishing Company.
  • Belland, B. R. (2010). Portraits of middle school students constructing evidence-based arguments during problem-based learning: The impact of computer-based scaffolds. Educational technology research and Development 58(3), 285-309.
  • Belland, B. R., Glazewski, K. D., & Richardson, J. C. (2011). Problem-based learning and argumentation: Testing a scaffolding framework to support middle school students’ creation of evidence-based arguments. Instructional Science, 39(5), 667-694.
  • Boud, D., & Feletti, G. (2013). The challenge of problem-based learning. Routledge.
  • Bouwma‐Gearhart, J., Stewart, J., & Brown, K. (2009). Student misapplication of a gas‐like model to explain particle movement in heated solids: implications for curriculum and instruction towards students’ creation and revision of accurate explanatory models. International Journal of Science Education, 31(9), 1157-1174.
  • Camp, G. (1996). Problem-based learning: A paradigm shifts or a passing fad? Medical Education Online, 1(1), 4282.
  • Cassel, D. G. (2002). Synergistic argumentation in a problem-centered learning environment. Doctoral dissertation, The University of Oklahoma, Oklahoma
  • Chin, C., & Chia, L. G. (2004). Problem‐based learning: Using students' questions to drive knowledge construction. Science Education, 88 (5), 707-727.
  • Cohen, J. (1988). Statistical power analysis for the behavioral sciences (2nd ed.). Hillsdale, NJ: Erlbaum.
  • Creswell, J. W. (2002). Educational research: Planning, conducting, and evaluating quantitative (pp. 146-166). Upper Saddle River, NJ: Prentice Hall.
  • Çelik, A. Y., & Kılıç, Z. (2014). The impact of argumentation on high school chemistry students’ conceptual understanding, attitude towards chemistry and argumentativeness. Eurasian Journal of Physics and Chemistry Education, 6(1).
  • Dahlgren, M. A., Castensson, R., & Dahlgren, L. O. (1998). PBL from the teachers' perspective. Higher Education, 36 (4), 437-447.
  • Dobbs, V. (2008). Comparing Student Achievement in The Problem-Based Learning Classroom and Traditional Teaching Methods Classroom. ProQuest Information and Learning.
  • Dochy, F., Segers, M., Van den Bossche, P. & Gijbels, D. (2003). Effects of problem-based Learning: a meta-analysis. Learning and Instruction, 13 (5), 533–568.
  • Donnel, C. M., O’Connor, C. and Seery, M. K. (2007). Developing practical chemistry skills by means of student-driven problem-based learning mini-projects. Chemistry Education Research and Practice, 8 (2), 130-139.
  • Driver, R., Asoko, H., Leach, J., Scott, P., & Mortimer, E. (1994). Constructing scientific knowledge in the classroom. Educational researcher, 23(7), 5-12.
  • Driver, R., Newton, P., & Osborne, J. (2000). Establishing the norms of scientific argumentation in classrooms. Science education, 84 (3), 287-312.
  • Duch, B. J., Groh, S. E. & Allen, D. E. (2001). The power of problem-based learning. Stylus Publishing. Virginia (USA).
  • Duschl, R. A., & Osborne, J. (2002). Supporting and promoting argumentation discourse in science education. Studies in Science Education, 38(1), 39-72).
  • Erduran, S., & Jiménez-Aleixandre, M. P. (2008). Argumentation in science education. Perspectives from Classroom-Based Research. Dordre-cht: Springer.
  • Erduran, S., & Mugaloglu, E. Z. (2013). Interactions of economics of science and science education: Investigating the implications for science teaching and learning. Science & Education, 22(10), 2405-2425.
  • Erduran, S., & Pabuccu, A. (2012). Bonding chemistry and argument: teaching and learning argumentation through chemistry stories. Bristol: University of Bristol.
  • Etherington, M.B. (2011) Investigative primary science: A problem-based learning approach, Australian Journal of Teacher Education, Vol. 36, Issue 9, pp 53-74).
  • Ford, M. (2008). Disciplinary authority and accountability in scientific practice and learning. Science Education, 92 (3), 404-423.
  • Garnett, P.J. & Treagust, D.F. (1992). Conceptual difficulties experienced by senior high school students of chemistry: electrochemical (galvanic) and electrolytic cells, Journal of Research in Science Teaching, 29, 10, 1079-1099.
  • Gultepe, N., & Kilic, Z. (2015). Effect of scientific argumentation on the development of scientific process skills in the context of teaching chemistry. International Journal of Environmental and Science Education, 10(1), 111-132.
  • Greenwood J. D. (1999). Understanding the “Cognitive Revolution” in Psychology. Journal of the History of the Behavioral Sciences, 35(1), 1-22).
  • Groh, S. E. (2001). Using problem-based learning in general chemistry. (Eds.: Allen Deborah E.). The Power of Problem-Based Learning: A Practical "how to" for Teaching Undergraduate Courses in Any discipline (pp. 207).
  • Hefter, M. H., Berthold, K., Renkl, A., Riess, W., Schmid, S., & Fries, S. (2014). Effects of a training intervention to foster argumentation skills while processing conflicting scientific positions. Instructional Science, 42, 929-947.
  • Hmelo-Silver, C. E. (2004). Problem-based learning: What and how do students learn? Educational psychology review, 16(3), 235-266.
  • Hmelo-Silver, C. E., & Barrows, H. S. (2008). Facilitating collaborative knowledge building. Cognition and instruction, 26(1), 48-94.
  • Hmelo S. & Cindy E. (2004) Problem-Based Learning: What and How do students learn? Educational Psychology Review. 2004; 16:235-66;
  • Jiménez‐Aleixandre, M. P., Bugallo Rodríguez, A., & Duschl, R. A. (2000). “Doing the lesson” or “doing science”: Argument in high school genetics. Science Education, 84(6), 757-792.
  • Jiménez-Aleixandre, M. P., & Pereiro-Muñoz, C. (2005). Argument construction and change while working on a real environment problem. In Research and the quality of science education (pp. 419-431). Springer, Dordrecht.
  • Joung, S. (2003). The effects of high-structure cooperative versus low-structure collaborative design on online debate in terms of decision making, critical thinking, and interaction pattern. Doctoral Dissertation, The Florida State University, Florida.
  • Jonassen, D. H. (2011). Design Problems for Secondary Students. National Center for Engineering and Technology Education.
  • Ju, H., & Choi, I. (2018). The Role of Argumentation in Hypothetico-Deductive Reasoning During Problem-Based Learning in Medical Education: A Conceptual Framework. Interdisciplinary Journal of Problem-Based Learning, 12(1), 4.
  • Kelly, O., & Finlayson, O. (2009). A hurdle too high? Students’ experience of a PBL laboratory module. Chemistry Education Research and Practice, 10(1), 42-52.
  • Larive, C. K. (2004). Problem-based learning in the analytical chemistry laboratory course. Analytical and Bioanalytical Chemistry, 380 (3), 357-359.
  • Mann, M., Treagust, D. F. (1998). A pencil and paper instrument to diagnose students’ conception of breathing, gas exchange and respiration, Australian Science Teachers Journal, 44, 2, 55-59.
  • Marklin Reynolds, J., & Hancock, D. R. (2010). Problem‐based learning in a higher education environmental biotechnology course. Innovations in Education and Teaching International, 47 (2), 175-186.
  • McDonald, J.T., 2002. Using problem-based learning in a science methods course. Proceedings of the Annual International Conference of the Association for the Education of Teachers in Science, ERİC ED 465 621, Charlotte.
  • McGhee, M. (2015). The effects of argumentation scaffolding in a problem-based learning course on problem-solving outcomes and learner motivation. Doctoral Dissertation, The Florida State University.
  • Mehalik, M. M., Doppelt, Y., & Schuun, C. D. (2008). Middle‐school science through design‐based learning versus scripted inquiry: Better overall science concept learning and equity gap reduction. Journal of Engineering Education, 97(1), 71-85.
  • Noh, T., & Scharmann, L. C. (1997). Instructional influence of a molecular‐level pictorial presentation of matter on students' conceptions and problem‐solving ability. Journal of Research in Science Teaching: The Official Journal of the National Association for Research in Science Teaching, 34(2), 199-217.
  • Nussbaum, E. M., & Edwards, O. V. (2011). Critical questions and argument stratagems: A framework for enhancing and analyzing students’ reasoning practices. The Journal of the Learning Sciences, 1-46.
  • Osborne, J., Erduran, S. & Simon, S. (2004). Enhancing the quality of argumentation in school science. Journal of Research in Science Teaching, 41 (10), 994-1020.
  • Osborne, J., Erduran, S., Simon, S., & Monk, M. (2001). Enhancing the quality of argument in school science. School science review, 82(301), 63-70.
  • Özmen, H. (2011). Effect of animation enhanced conceptual change texts on 6th grade students’ understanding of the particulate nature of matter and transformation during phase changes. Computers & Education, 57(1), 1114-1126.
  • Papastergiou, M. (2009). Digital game-based learning in high school computer science education: Impact on educational effectiveness and student motivation. Computers & Education, 52(1), 1-12.
  • Pepper, C. (2010). ‘There’s a lot of learning going on but NOT much teaching!’: student perceptions of problem‐based learning in science. Higher Education Research & Development, 29 (6), 693-707.
  • Peterson, R. F. & Treagust, D. F. (1998). Learning to teach primary science through problem-based learning. Science Education, 82 (2), 215-237.
  • Ramstedt, M., Hedlund, T., Björn, E., Fick, J., & Jahnke, I. (2016). Rethinking chemistry in higher education towards technology enhanced problem-based learning. Education Inquiry, 7 (2).
  • Ronis, D. L. (2007). Problem-based learning for math & science: Integrating inquiry and the internet. Corwin.
  • Sağır, Ş. U., & Kılıç, Z. (2012). Analysis of the Contribution of Argumentation-Based Science Teaching on Student Success and Retention. Eurasian Journal of Physics & Chemistry Education, 4(2).
  • Savery, J. R. (2006). Overview of problem-based learning: Definitions and distinctions. Interdisciplinary Journal of Problem-based Learning, 1(1), 3.
  • Schwartz, P., Webb, G., & Mennin, S. (Eds.). (2001). Problem-based learning: Case studies, experience and practice. Psychology Press.
  • Skamp, K. (1999). Are Atoms and Molecules Too Difficult for Primary Children? School Science Review, 81(295), 87-96.
  • Torp, L. & Sage, S. (2002). Problem as Possibilities: Problem-Based Learning for K-16 Education. Alexandria, VA, USA: Association for Supervision and Curriculum Development.
  • Treagust, D. F. (1988). Development and use of diagnostic tests to evaluate students’ misconceptions in science. International journal of science education, 10(2), 159-169.
  • Tüysüz, C., Demirel, O. E., & Yildirim, B. (2013). Investigating the effects of argumentation, problem and laboratory-based instruction approaches on pre-service teachers’ achievement concerning the concept of “acid and base”. Procedia-Social and Behavioral Sciences, 93, 1376-1381.
  • Velez, A. B. (2008). Thinking critically together: The intellectual and discursive of controversial conversations. Doctoral Dissertation, The Harvard University, Massachusetts.
  • Vernon, D. T., & Blake, R. L. (1993). Does problem-based learning work? A meta-analysis of evaluative research. Academic medicine, 68 (7), 550-63.
  • Voska, K. W., Heikkinen, H. W. (2000). Identification and analysis of student conception used to solve chemical equilibrium problems, Journal of Research in Science Teaching, 37, 2, 160-176.
  • Walton, D. (2007). Media argumentation: dialectic, persuasion and rhetoric. Cambridge University Press.
  • West, T. L. (1994). The effect of argumentation instruction on critical thinking skills. Doctoral Dissertation. Southern Illinois University, Chicago.
  • Wood, D.F. (2003). Problem based learning, ABC of learning and teaching in medicine, 326 (7384): 328-330
  • Yuzhi, W. (2003). Using problem-based learning in teaching analytical chemistry. The China Papers, 2, 28-33.
Toplam 78 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Eğitim Üzerine Çalışmalar
Bölüm Makaleler
Yazarlar

Gülseda Eyceyurt Türk 0000-0002-4757-3696

Ziya Kılıç Bu kişi benim 0000-0002-7825-9608

Yayımlanma Tarihi 5 Haziran 2020
Yayımlandığı Sayı Yıl 2020

Kaynak Göster

APA Eyceyurt Türk, G., & Kılıç, Z. (2020). The Effect of Argumentation-supported Problem Based Learning on the Achievements of Science Teacher Candidates Regarding the Subjects of Gases and Acids-Bases. Bartın University Journal of Faculty of Education, 9(2), 440-463. https://doi.org/10.14686/buefad.643630

All the articles published in the journal are open access and distributed under the conditions of CommonsAttribution-NonCommercial 4.0 International License 

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Bartın University Journal of Faculty of Education