本論文的主要目標為探討在社會性科學議題的網路課程中，學生的學習歷程與論證表現。本論文根據研究架構分為四個不同的研究議題，第一個研究為模型建立的理論研究，以Mplus7檢驗三種不同科學認識觀的結構模型，了解三種科學認識觀所包含各面向之間的關連性及預測結構。第二個研究為研究方法的回顧性研究，探討當前眼球追蹤技術應用於科學教育研究的趨勢，然後根據文獻回顧的結果，提出未來運用眼球追蹤技術於科學教育中的研究架構，並根據所提出的建議設計後續的研究內容。第三個研究為實徵研究，探討大學生科學認識觀與論證結構的學習歷程與理解之關係。研究結果指出，當大學生持有越高程度的「確定性」信念時，會對於論證結構付出較少的認知注意力，導致較差的學習表現。第四個研究亦為實徵研究，欲了解融入社會性科學議題的生物醫學網路課程中，大學生的認知學習歷程、論證表現以及個人因素(例如：先備知識、科學認識觀、網路搜尋行為等)對於學習的影響。研究結果發現，學生的認知學習歷程以及論證表現和個人因素皆有其相關性存在。各研究結果皆支持此論文的研究架構，且根據研究結果提出教育上的意涵以及未來研究建議。

The ultimate goal of this thesis was to investigate how students reason and evaluate a biomedical socio-scientific issue (SSI). To reach the goal, we prepared several studies that were theoretically, methodologically and empirically related. Previous studies have indicated that some psychological factors may affect students’ cognitive process during learning and their argument performances. Among these factors, epistemic beliefs in science have been frequently mentioned and discussed. In literature, various forms of epistemic beliefs related to reasoning can be found. However, the associations between different epistemic beliefs have not been thoroughly examined. In study 1 (Chapter 2), we examined the associations among beliefs about the nature of knowledge, beliefs about the justification for knowing in science and Internet-specific justification, and then tested a structural model of these epistemic beliefs . In this thesis, a key method for empirical studies was the eye tracking method. Although the eye tracking method has been used by psychological and educational researchers, how this method can be applied specifically to investigate processes of science learning has not been systemically examined. Therefore, the second study of this thesis (presented in Chapter 3) was a methodologically literature review to analyze the research issue, research design and learning dimensions of studies in science education, which apply the eye tracking method. Based on the review result, we applied an inherent eye tracking design to explore information processing behaviors associated with the learning activities involved in the thesis research. Given that the ultimate goal of the study was related to the practice of argumentative reasoning on a SSI, it was hypothesized that the personal epistemic beliefs in science should interact with the understanding about the argument structure. We conducted empirical studies to test the interactions. Accordingly, in Study 3 (Chapter 4), the associations among different types of epistemic beliefs in science, learning of argument structure and understanding of the argument structure were analyzed. At last, another empirical study as presented in Study 4 (Chapter 5) was designed to investigate how students reasoned about a biomedical issue involved in the study. Factors explored in Study 1-3 were taken into consideration in the design. In Study 4, an online learning environment was created first, which allowed students to learn basic scientific knowledge, read the socio-scientific issue with selected articles, search related information through the Internet, and present their opinions. University learners were asked to learn and evaluate the biomedical issue discussed in the study in the online learning environment. Afterwards, we examined the effects of epistemic beliefs, students’ information processing behaviors during the online activities and the uses of argument components in the context of the biomedical issue. The result showed that students’ attention to the online SSI lesson and the web search result were positively correlated with the change in argument performance. Especially, attention to warrant for the opposing opinion positively predicted the change. Interactions among argument performances, visual attention during learning and epistemic beliefs in science were found. Based on the study results as presented in Chapter 2 to 5, suggestions for future research and implications for science education were provided in Chapter 6.

Chapter1:
Bell, P., & Linn, M.C. (2000). Scientific arguments as learning artifacts: Designing for learning from the web with KIE. International Journal of Science Education, 22, 797-817.
Berland, L., & Reiser, B. (2009). Making sense of argumentation and explanation. Science Education, 93(1), 26-55.
Bråten, I., Brandmo, C., & Kammerer, Y. (2018). A Validation Study of the Internet-Specific Epistemic Justification Inventory With Norwegian Preservice Teachers. Journal of Educational Computing Research, 0(0), 1-24
Bråten, I., Strømsø, H. I., & Samuelstuen, M. S. (2005). The relationship between Internet-specific epistemological beliefs and learning within Internet technologies. Journal of Educational Computing Research, 33, 141-171.
Chen, Y. C., & Yang, F. Y. (2014). Probing the relationship between process of spatial problems solving and science learning: An eye tracking approach. International Journal of Science & Mathematics Education, 12(3), 579-603.
Chin, C. C., Yang, W. C., & Tuan, H. L. (2016). Argumentation in a socioscientific context and its influence on fundamental and derived science literacies. International Journal of Science and Mathematics Education, 14(4), 603-617.
Chiu, Y. L., Tsai, C. C., & Liang, J. C. (2015). Testing measurement invariance and latent mean differences across gender groups in college students’ Internet-specific epistemic beliefs. Australasian Journal of Educational Technology, 31, 486-499.
Conley, A. M., Pintrich, P. R., Vekiri, I. & Harrison, D. (2004). Changes in epistemological beliefs in elementary science students. Contemporary Educational Psychology, 29(2), 186-204.
Driver, R., Newton, P., & Osborne, J. (2000). Establishing the norms of scientific argumentation in classrooms. Science Education, 84(3), 287-312.
Duschl, R., & Osborne, J. (2002). Supporting and promoting argumentation discourse in science education. Studies in Science Education, 38, 39-72.
Erduran, S., Simon, S., & Osborne, J. (2004). TAPping into argumentation: Developments in the application of Toulmin's argument pattern for studying science discourse. Science education, 88(6), 915-933.
Ferguson, L.E., & Bråten, I. (2013). Student profiles of knowledge and epistemic beliefs: Changes and relations to multiple-text comprehension. Learning and Instruction, 25, 49-61.
Greene, J. A., & Yu, S. B. (2015). Educating critical thinkers: The role of epistemic cognition. Policy Insights from the Behavioral and Brain Sciences, 3, 45-53.
Greene, J. A., Azevedo, R., & Torney-Purta, J. (2008). Modeling epistemic and ontological cognition: Philosophical perspectives and methodological directions. Educational Psychologist, 43, 142-160.
Ho, H. Y., Chang, T. L., Lee, T. N., Chou, C. C., Hsiao, S. H., Chen, Y. H., & Lu, Y. L. (2019). Above-and below-average students think differently: Their scientific argumentation patterns. Thinking Skills and Creativity, 34, 100607.
Hofer, B. K. (2000). Dimensionality and disciplinary differences in personal epistemology. Contemporary educational psychology, 25(4), 378-405.
Lai, M. L., Tsai, M. J., Yang, F. Y., Hsu, C. Y., Liu, T. C., Lee, S. W. Y., Lee, M. H., Chiou, G. L., Liang, J. C., & Tsai, C. C. (2013). A review of using eye-tracking technology in exploring learning from 2000 to 2012. Educational research review, 10, 90-115.
Larson, A., & Britt, A. (2009). Improving students’ evaluation of informal arguments. The Journal of Experimental Education, 77(4), 339-365.
Lee, W. C., Chiu, Y. L., Liang, J. C., & Tsai, C. C. (2014). Exploring the structural relationships between high school students’ Internet-specific epistemic beliefs and their utilization of online academic help seeking. Computers in Human Behavior, 36, 391-400.
Liang, J. C. & Tsai, C. C. (2010). Relational analysis of college science-major students’ epistemological beliefs toward science and conceptions of learning science. International Journal of Science Education, 32(17), 2273-2289.
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Sadler, T. D., Romine, W. L., & Topçu, M. S. (2016). Learning science content through socio-scientific issues-based instruction: A multi-level assessment study. International Journal of Science Education, 38(10), 1622-1635.
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Yang, F. Y., & Tsai, C. C. (2010). Reasoning about science-related uncertain issues and epistemological perspectives among children. Instructional Science, 38, 325-354.
Yang, F. Y., Bhagat, K. K., & Cheng, C. H. (2019). Associations of epistemic beliefs in science and scientific reasoning in university students from Taiwan and India. International Journal of Science Education, 41(10), 1347-1365.
Yang, F. Y., Chen, Y. H., & Tsai, M. J. (2013). How university students evaluate online information about a socio-scientific issue and the relationship with their epistemic beliefs. Journal of Educational Technology & Society, 16(3), 385-399.
Yang, F. Y., Huang, R. T., & Tsai, C.C. (2016). The effects of epistemic beliefs in science and gender difference on university students’ science-text reading: An eye-tracking study. International Journal of Science and Mathematics Eduction, 14, 473-498.

Chapter2:
Abd-El-Khalick, F. (2013). Teaching with and about nature of science, and science teacher knowledge domains. Science & Education, 22(9), 2087-2107.
Bentler, P. M. (1990). Comparative fit indexes in structural models. Psychological Bulletin, 107, 238-246.
Brandmo, C., & Bråten, I. (2018). Investigating relations between beliefs about justification for knowing, interest, and knowledge across two socio-scientific topics. Learning and Indiidual Differences, 62, 89-97.
Bråten, I., Brandmo, C., & Kammerer, Y. (2018). A Validation Study of the Internet-Specific Epistemic Justification Inventory With Norwegian Preservice Teachers. Journal of Educational Computing Research, 0(0), 1-24.
Bråten, I., Ferguson, L. E., Strømsø, H. I., & Anmarkrud, Ø. (2013). Justification beliefs and multiple documents comprehension. European Journal of Psychology of Education, 28(3), 879-902.
Bråten, I., Ferguson, L. E., Strømsø, H. I., & Anmarkrud, Ø. (2014). Students working with multiple conflicting documents on a scientific issue: Relations between epistemic cognition while reading and sourcing and argumentation in essays. British Journal of Educational Psychology, 84(1), 58-85.
Bråten, I., Strømsø, H. I., & Samuelstuen, M. S. (2005). The relationship between Internet-specific epistemological beliefs and learning within Internet technologies. Journal of Educational Computing Research, 33, 141-171.
Chen, J. A., & Pajares, F. (2010). Implicit theories of ability of Grade 6 science students: Relation to epistemological beliefs and academic motivation and achievement in science. Contemporary Educational Psychology, 35(1), 75-87.
Chiu, Y. L., Tsai, C. C., & Liang, J. C. (2015). Testing measurement invariance and latent mean differences across gender groups in college students’ Internet-specific epistemic beliefs. Australasian Journal of Educational Technology, 31, 486-499.
Chiu, Y. L., Liang, J. C., & Tsai, C. C. (2013). Internet-specific epistemic beliefs and self-regulated learning in online academic information searching. Metacognition Learning, 8, 235-260.
Conley, A. M., Pintrich, P. R., Vekiri, I. & Harrison, D. (2004). Changes in epistemological beliefs in elementary science students. Contemporary Educational Psychology, 29(2), 186-204.
Ferguson, L. E., Bråten, I., & Strømsø, H. I. (2012). Epistemic cognition when students read multiple documents containing conflicting scientific evidence: A think-aloud study. Learning and Instruction, 22, 103-120.
Ferguson, L.E., & Bråten, I. (2013). Student profiles of knowledge and epistemic beliefs: Changes and relations to multiple-text comprehension. Learning and Instruction, 25, 49-61.
Greene, J. A., Azevedo, R., & Torney-Purta, J. (2008). Modeling epistemic and ontological cognition: Philosophical perspectives and methodological directions. Educational Psychologist, 43, 142-160.
Hofer, B. K. (2016). Epistemic cognition as a psychological construct: Advancements and challenges. Handbook of epistemic cognition, 31-50.
Hofer, B. K., & Pintrich, P. R. (1997). The development of epistemological theories: Beliefs about knowledge and knowing and their relation to learning. Review of Educational Research, 67, 88-140.
Hsu, C. Y., Tsai, M. J., Hou, H. T., & Tsai, C. C. (2014). Epistemic beliefs, online search strategies, and behavioral patterns while exploring socioscientific issues. Journal of Science Education and Technology, 23(3), 471-480.
Kizilgunes, B., Tekkaya, C., & Sungur, S. (2009). Modeling the relations among students' epistemological beliefs, motivation, learning approach, and achievement. The Journal of educational research, 102(4), 243-256.
Ku, K.Y.L., Lai, E.C.M., & Hau, K.T. (2014). Epistemological beliefs and the effect of authority on argument-counterargument integration: An experiment. Thinking Skills and Creativity, 13, 67-79.
Lederman, N. G. (2007). Nature of science: Past, present, and future. Handbook of research on science education, 2, 831-879.
Lee, W. C., Chiu, Y. L., Liang, J. C., & Tsai, C. C. (2014). Exploring the structural relationships between high school students’ Internet-specific epistemic beliefs and their utilization of online academic help seeking. Computers in Human Behavior, 36, 391-400.
Liang, J. C., & Tsai, C. C. (2010). Relational analysis of college science‐major students’ epistemological beliefs toward science and conceptions of learning science. International Journal of Science Education, 32(17), 2273-2289.
Liang, J. C., Lee, M. H., & Tsai, C. C. (2010). The Relations Between Scientific Epistemological Beliefs and Approaches to Learning Science Among Science-Major Undergraduates in Taiwan. Asia-Pacific Education Researcher, 19(1), 43-59.
Lin, Y. C., Liang, J. C., & Tsai, C. C. (2012). The relationships between epistemic beliefs in biology and approaches to learning biology among biology-major university students in Taiwan. Journal of Science Education and Technology, 21(6), 796-807.
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Mason, L., Gava, M., & Boldrin, A. (2008). On warm conceptual change: The interplay of text, epistemological beliefs, and topic interest. Journal of Educational Psychology, 100(2), 291-309.
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Noroozi, O. (2018). Considering students’ epistemic beliefs to facilitate their argumentative discourse and attitudinal change with a digital dialogue game. Innovations in Education and Teaching International, 55(3), 357-365.
Nussbaum, E. M., Sinatra, G. M., & Poliquin, A. (2008). Role of epistemic beliefs and scientific argumentation in science learning. International Journal of Science Education, 30(15), 1977-1999.
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Tsai, C. C., Ho, H. N. J., Liang, J. C., & Lin, H. M. (2011). Scientific epistemic beliefs, conceptions of learning science and self-efficacy of learning science among high school students. Learning and Instruction, 21(6), 757-769.
Wu, Y. T., & Tsai, C. C. (2011). High school students’ informal reasoning regarding a socio‐scientific issue, with relation to scientific epistemological beliefs and cognitive structures. International Journal of Science Education, 33(3), 371-400.
Yang, F. Y., Bhagat, K. K., & Cheng, C. H. (2019). Associations of epistemic beliefs in science and scientific reasoning in university students from Taiwan and India. International Journal of Science Education, 41(10), 1347-1365.
Yang, F. Y., Chang, C. C., Chen, L. L., & Chen, Y. C. (2016). Exploring learners’ beliefs about science reading and scientific epistemic beliefs, and their relations with science text understanding. International Journal of Science Education, 38, 1591-1606.
Yang, F. Y., Huang, R. T., & Tsai, I. J. (2016). The effects of epistemic beliefs in science and gender differences on university students’ science-text reading: An eye-tracking study. International Journal of Science and Mathematics Education, 14, 473-498.

Chapter3:
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Articles included in the review analysis
Ariasi, N., & Mason, L. (2014). From covert processes to overt outcomes of refutation text reading: The interplay of science text structure and working memory capacity through eye fixations. International Journal of Science and Mathematics Education, 12(3), 493-523.
Ariasi, N., Hyönä, J., Kaakinen, J. K., & Mason, L. (2017). An eye‐movement analysis of the refutation effect in reading science text. Journal of Computer Assisted Learning, 33(3), 202-221.
Chen, Y. C., & Yang, F. Y. (2014). Probing the relationship between process of spatial problems solving and science learning: An eye tracking approach. International Journal of Science & Mathematics Education, 12(3), 579-603.
Chien, K. P., Tsai, C. Y., Chen, H. L., Chang, W. H., & Chen, S. (2015). Learning differences and eye fixation patterns in virtual and physical science laboratories. Computers & Education, 82, 191-201.
Chuang, H. H., & Liu, H. C. (2012). Effects of different multimedia presentations on viewers’ information-processing activities measured by eye-tracking technology. Journal of Science Education and Technology, 21(2), 276-286.
Hinze, S. R., Williamson, V. M., Shultz, M. J., Williamson, K. C., Deslongchamps, G., & Rapp, D. N. (2013). When do spatial abilities support student comprehension of STEM visualizations?. Cognitive processing, 14(2), 129-142.
Ho, H. N. J., Tsai, M. J., Wang, C. Y., & Tsai, C. C. (2014). Prior knowledge and online inquiry-based science reading: Evidence from eye tracking. International Journal of Science and Mathematics Education, 12(3), 525-554.
Hochpöchler, U., Schnotz, W., Rasch, T., Ullrich, M., Horz, H., McElvany, N., & Baumert, J. (2013). Dynamics of mental model construction from text and graphics. European journal of psychology of education, 28(4), 1105-1126.
Jarodzka, H., Balslev, T., Holmqvist, K., Nyström, M., Scheiter, K., Gerjets, P., & Eika, B. (2012). Conveying clinical reasoning based on visual observation via eye-movement modelling examples. Instructional Science, 40(5), 813-827.
Jian, Y. C. (2016). Fourth graders' cognitive processes and learning strategies for reading illustrated biology texts: eye movement measurements. Reading Research Quarterly, 51(1), 93-109.
Jian, Y. C. (2017). Eye-movement patterns and reader characteristics of students with good and poor performance when reading scientific text with diagrams. Reading and Writing, 30(7), 1447-1472.
Jian, Y. C., & Ko, H. W. (2017). Influences of text difficulty and reading ability on learning illustrated science texts for children: An eye movement study. Computers & Education, 113, 263-279
Jian, Y. C. (2018). Reading Instructions Influence Cognitive Processes of Illustrated Text Reading Not Subject Perception: An Eye-Tracking Study. Frontiers in Psychology, 9, 2263.
Jian, Y. C. (2019). Reading instructions facilitate signaling effect on science text for young readers: an eye-movement study. International Journal of Science and Mathematics Education, 17(3), 503-522.
Jung, Y. J., Zimmerman, H. T., & Pérez-Edgar, K. (2018). A methodological case study with mobile eye-tracking of child interaction in a science museum. TechTrends, 62(5), 509-517.
Korbach, A., Brünken, R., & Park, B. (2017). Measurement of cognitive load in multimedia learning: A comparison of different objective measures. Instructional Science, 45(4), 515-536.
Lenzner, A., Schnotz, W., & Müller, A. (2013). The role of decorative pictures in learning. Instructional Science, 41(5), 811-831.
Lim, S., Kim, Y., & Yang, I. (2014). An analysis of students' understanding process about an illustraion and text related to the earth system: An eye-tracking study. International Information Institute (Tokyo). Information, 17(8), 3613.
Lin, L., Lee, C. H., Kalyuga, S., Wang, Y., Guan, S., & Wu, H. (2017). The effect of learner-generated drawing and imagination in comprehending a science text. The Journal of Experimental Education, 85(1), 142-154.
Lindner, M. A., Eitel, A., Strobel, B., & Köller, O. (2017). Identifying processes underlying the multimedia effect in testing: An eye-movement analysis. Learning and instruction, 47, 91-102.
Lin, Y. Y., Holmqvist, K., Miyoshi, K., & Ashida, H. (2017). Effects of detailed illustrations on science learning: an eye-tracking study. Instructional science, 45(5), 557-581.
Mason, L., Pluchino, P., & Tornatora, M. C. (2013). Effects of picture labeling on science text processing and learning: Evidence from eye movements. Reading Research Quarterly, 48(2), 199-214.
Mason, L., Pluchino, P., & Tornatora, M. C. (2015). Eye-movement modeling of integrative reading of an illustrated text: Effects on processing and learning. Contemporary Educational Psychology, 41, 172-187.
Mason, L., Pluchino, P., Tornatora, M. C., & Ariasi, N. (2013). An eye-tracking study of learning from science text with concrete and abstract illustrations. The Journal of Experimental Education, 81(3), 356-384.
Mason, L., Tornatora, M. C., & Pluchino, P. (2013). Do fourth graders integrate text and picture in processing and learning from an illustrated science text? Evidence from eye-movement patterns. Computers & Education, 60(1), 95-109.
Mason, L., Tornatora, M. C., & Pluchino, P. (2015). Integrative processing of verbal and graphical information during re-reading predicts learning from illustrated text: An eye-movement study. Reading and Writing, 28(6), 851-872.
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Rau, M. A., Michaelis, J. E., & Fay, N. (2015). Connection making between multiple graphical representations: A multi-methods approach for domain-specific grounding of an intelligent tutoring system for chemistry. Computers & Education, 82, 460-485.
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Yang, F. Y., Huang, R. T., & Tsai, I. J. (2016). The effects of epistemic beliefs in science and gender difference on university students’ science-text reading: an eye-tracking study. International Journal of Science and Mathematics Education, 14(3), 473-498.
Yang, F. Y. (2017). Examining the reasoning of conflicting science information from the information processing perspective—an eye movement analysis. Journal of Research in Science Teaching, 54(10), 1347-1372.

Chapter4:
Bell, P., & Linn, M. C. (2000). Scientific arguments as learning artifacts: Designing for learning from the Web with KIE. International Journal of Science Education, 22(8), 797-817.
Berland, L. K., & Reiser, B. J. (2009). Making sense of argumentation and explanation. Science Education, 93(1), 26-55.
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Bricker, L. A., & Bell, P. (2008). Conceptualizations of argumentation from science studies and the learning sciences and their implications for the practices of science education. Science Education, 92(3), 473-498.
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Duschl, R. (2008). Science education in three-part harmony: Balancing conceptual, epistemic, and social learning goals. Review of Research in Education, 32, 268-291.
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Sampson, V., Enderle, P., & Grooms, J. (2013). Argumentation in science education. The Science Teacher, 80(5), 30.
Stathopoulou, C., & Vosnidou, S. (2007). Conceptual change in physics and physics-related epistemological beliefs: A relationship under scrutiny. In S. Vosnidou, A. Baltas, & X. Vamvakoussi (Eds.), Re-framing the problem of conceptual change in learning and instruction (pp. 145-163). Amsterdam, The Netherlands: Elsevier.
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Yang, F. Y. (2005). Student views concerning evidence and the expert in reasoning a socio‐scientific issue and personal epistemology. Educational Studies, 31(1), 65-84.
Yang, F. Y. (2017). Examining the reasoning of conflicting science information from the information processing perspective—an eye movement analysis. Journal of Research in Science Teaching, 54(10), 1347-1372.
Yang, F. Y., & Tsai, C. C. (2010). Reasoning about science-related uncertain issues and epistemological perspectives among children. Instructional Science, 38(4), 325-354.
Yang, F. Y., Bhagat, K. K., & Cheng, C. H. (2019). Associations of epistemic beliefs in science and scientific reasoning in university students from Taiwan and India. International Journal of Science Education, 41(10), 1347-1365.

Chapter5:
Darley, W. K., Blankson, C., & Luethge, D. J. (2010). Toward an integrated framework for online consumer behavior and decision making process: A review. Psychology & marketing, 27(2), 94-116.
Driver, R., Newton, P., & Osborne, J. (2000). Establishing the norms of scientific argumentation in classrooms. Science Education, 84(3), 287-312.
Erduran, S., Simon, S., & Osborne, J. (2004). TAPing into argumentation: Developments in the use of Toulmin’s argument pattern in studying science discourse. Science Education, 88(6), 915-933.
Oulton, C., Dillon, J., & Grace, M. M. (2004). Reconceptualizing the teaching of controversial issues. International Journal of Science Education, 26(4), 411-423.
Roscoe, R. D., Grebitus, C., O'Brian, J., Johnson, A. C., & Kula, I. (2016). Online information search and decision making: Effects of web search stance. Computers in Human Behavior, 56, 103-118.
Sadler, T. D. (2004). Informal reasoning regarding socioscientific issues: A critical review of research. Journal of Research in Science Teaching, 41, 513-536.
Sadler, T. D., and Donnelly, L. A., 2006. “Socioscientific Argumentation: The Effects of Content Knowledge and Morality.” International Journal of Science Education 28(12), 1463-1488.
Sadler, T. D., Romine, W. L., & Topçu, M. S. (2016). Learning science content through socio-scientific issues-based instruction: A multi-level assessment study. International Journal of Science Education, 38(10), 1622-1635.
Yang, F. Y., & Tsai, C. C. (2010). An epistemic framework for scientific reasoning in informal contexts. In L. D. Bendixen & F. C. Feucht (Eds.), Personal epistemology in the classroom (pp. 124–162). Cambridge, UK: Cambridge University Press.
Yang, F. Y., Huang, R. T., & Tsai, C.C. (2016). The effects of epistemic beliefs in science and gender difference on university students’ science-text reading: An eye-tracking study. International Journal of Science and Mathematics Eduction, 14, 473-498.
Zeidler, D. L. (2001). Participating in program development: Standard F. In D. Siebert & W. McIntosh (Eds.), College pathways to the science education standards (pp. 18 – 22). Arlington, VA: National Science Teachers Press.
Zeidler, D. L., & Keefer, M. (2003). The role of moral reasoning and the status of socioscientific issues in science education: Philosophical, psychological and pedagogical considerations. In D. L. Zeidler (Ed.), The role of moral reasoning on socioscientific issues and discourse in science education. Dordrecht: Kluwer Academic Publishers.
Zeidler, D. L., Osborne, J., Erduran, S., Simon, S., & Monk, M. (2003). The role of argument and fallacies during discourse about socioscientific issues. In D. L. Zeidler (Ed.), The role of moral reasoning on socioscientific issues and discourse in science education. Dordrecht: Kluwer Academic Press.

Chapter6:
Hofer, B. K. (2016). Epistemic cognition as a psychological construct: Advancements and challenges. Handbook of epistemic cognition, 31-50.
Yang, F. Y., Bhagat, K. K., & Cheng, C. H. (2019). Associations of epistemic beliefs in science and scientific reasoning in university students from Taiwan and India. International Journal of Science Education, 41(10), 1347-1365.
Hofer, B. K., & Pintrich, P. R. (1997). The development of epistemological theories: Beliefs about knowledge and knowing and their relation to learning. Review of Educational Research, 67, 88-140.
Sampson, V., Enderle, P., & Grooms, J. (2013). Argumentation in science education. The Science Teacher, 80(5), 30.