Construction and Practice of Online-Offline Hybrid Teaching Mode for University Chemistry Courses under the Background of “Internet+”

[1] Luft, Julie A. (2020). Constructing explanations in an active learning preparatory Chemistry course. Journal of Chemical Education, 97. Search in Google Scholar

[2] Juan, L. (2017). Practical exploration of inquiry teaching method inChemistry teaching of higher vocational colleges. International Journal of Technology, Management. Search in Google Scholar

[3] Yang, H., Kim, M., & Seongjoo, K. (2020). The effects of design thinking in high school Chemistry classes. Journal of The Korean Chemical Society, 64, 159-174. Search in Google Scholar

[4] Angela, A., Nicola, C., Corrado, C., Aurelia, F., Anna, M., & Rosanna, R. (2018). Ochemdb: the free online open Chemistry database portal for searching and analysing crystal structure information. Journal of Applied Crystallography, 51(4). Search in Google Scholar

[5] L.D. Martínez-Argüello, Hinojo-Lucena, F. J., & I.A. Díaz. (2018). Application of information and communication technologies (itc) in teaching-learning processes by Chemistry teachers. Informacion Tecnologica, 29(2), 41-52. Search in Google Scholar

[6] Lapierre, K. R., & Flynn, A. B. (2020). An online categorization task to investigate changes in students’ interpretations of organic Chemistry reactions. Journal of Research in Science Teaching, 57(1). Search in Google Scholar

[7] Negru, Bogdan. (2020). Teaching upper division Chemistry and bioChemistry capstone lab courses during a pandemic. Journal of Chemical Education, 97. Search in Google Scholar

[8] Choi, S., Song, N., & Noh, T. (2017). The characteristics of curriculum design of pre-service Chemistry teachers participating in educational program for teaching in science museum. Journal of the Korean Chemical Society, 61(6), 388-401. Search in Google Scholar

[9] Jonathon, Grooms, Victor, Sampson, Patrick, & Enderle. (2018). How concept familiarity and experience with scientific argumentation are related to the way groups participate in an episode of argumentation. Journal of Research in Science Teaching. Search in Google Scholar

[10] Kim, T. T., Kim, H., & Han, S. (2018). Academic research inspired design of an expository organic Chemistry lab course. Journal of the Korean Chemical Society, 62(2), 99-105. Search in Google Scholar

[11] Canal, J. P., Goyan, R. L., & Mund, G. (2021). General Chemistry education in a pandemic. Canadian Journal of Chemistry(12). Search in Google Scholar

[12] Lazenby, K., Stricker, A., Brandriet, A., Rupp, C. A., & Becker, N. M. (2019). Mapping undergraduate Chemistry students’ epistemic ideas about models and modeling. Journal of Research in ence Teaching. Search in Google Scholar

[13] SM Lou. (2020). Reducing the prior-knowledge achievement gap by using technology-assisted guided learning in an undergraduate Chemistry course. Journal of research in science teaching(3), 57. Search in Google Scholar

[14] Payne, C., & Crippen, K. J. (2023). A structural model of student experiences in a career‐forward Chemistry laboratory curriculum. Journal of Research in Science Teaching. Search in Google Scholar

[15] He, P., Chen, I. C., Touitou, I., Bartz, K., Schneider, B., & Krajcik, J. (2023). Predicting student science achievement using post-unit assessment performances in a coherent high school Chemistry project-based learning system. Journal of research in science teaching. Search in Google Scholar

[16] Samon, S., & Levy, S. T. (2020). Interactions between reasoning about complex systems and conceptual understanding in learning Chemistry. Journal of Research in Science Teaching, 57(1). Search in Google Scholar

[17] Cha, J., Kan, S. Y., Wahab, N. H. A., Aziz, A. N., & Chia, P. W. (2017). Incorporation of brainteaser game in basic organic Chemistry course to enhance students’ attitude and academic achievement. Journal of the Korean Chemical Society, 61(4), 218-222. Search in Google Scholar

[18] Overman, M., Vermunt, J. D., Meijer, P. C., & Brekelmans, M. (2019). Teacher–student negotiations during context‐based Chemistry reform: a case study. Journal of Research in Science Teaching(13). Search in Google Scholar

[19] Cikmaz, A., Fulmer, G., Yaman, F., & Hand, B. (2021). Examining the interdependence in the growth of students’ language and argument competencies in replicative and generative learning environments. Journal of Research in Science Teaching. Search in Google Scholar

[20] Battino, & Rubin. (2018). Comments on the teaching of Chemistry, doing Chemistry demonstrations, and a passion for chemical thermodynamics. The Journal of Chemical Thermodynamics, 123, 74-78. Search in Google Scholar

[21] Lifei, D. (2020). The application of pbl teaching method in the practice course of analytical Chemistry. Magazine of Concrete Research, 2, 16-21. Search in Google Scholar

[22] Fentem, A., Beard, R., & Gopalan, C. (2018). Two case studies comparing flipped teaching and online teaching with the traditional lecture‐based teaching. The FASEB Journal, 32(S1), 773.16-773.16. Search in Google Scholar

[23] Bernholt, S., Broman, K., Siebert, S., & Parchmann, I. (2019). Digitising teaching and learning – additional perspectives for Chemistry education. Israel Journal of Chemistry, 59(6-7), 554-564. Search in Google Scholar

[24] Wenyan, N. (2020). Construction of network open teaching platform of analytical Chemistry based on facial recognition and artificial intelligence. Journal of Intelligent and Fuzzy Systems, 40(2), 1-11. Search in Google Scholar

[25] Ting, X. (2020). Chemistry course network teaching based on key information search and big data cloud platform. Journal of Intelligent and Fuzzy Systems, 40(3), 1-12. Search in Google Scholar

[26] Li, Z., & Jiang, W. (2022). Research on the teaching reform of inorganic Chemistry based on spoc and fcm during covid-19. Sustainability, 14. Search in Google Scholar

[27] Cho, J., & Baek, W. (2019). Identifying factors affecting the quality of teaching in basic science education: physics, biological sciences, mathematics, and Chemistry. Sustainability, 11(14), 3958. Search in Google Scholar

[28] Kennepohl, D. (2021). Laboratory activities to support online Chemistry courses: a literature review. Canadian Journal of Chemistry(11), 99. Search in Google Scholar

[29] Inbal Tuvi‐Arad, & Blonder, R. (2019). Technology in the service of pedagogy: teaching with Chemistry databases. Israel Journal of Chemistry, 59(6-7). Search in Google Scholar

[30] Chans, G. M., Mireille E. Bravo-Gutiérrez, Orona-Navar, A., & Elvia P. Sánchez-Rodríguez. (2022). Compilation of Chemistry experiments for an online laboratory course: student’s perception and learning outcomes in the context of covid-19. Sustainability, 14. Search in Google Scholar

[31] Harvey, B., Niamh, C., Williams, D. P., & Blackburn, R. A. R. (2023). Impact of the covid-19 pandemic on Chemistry student and staff perceptions of their learning/teaching experience. Journal of Chemical Education. Search in Google Scholar

[32] Nana Sun.(2024).A Strategic Study on the Construction of Ideological and Political Education in College Physical Education Class Based on Online and Offline Mixed Teaching Mode. International Journal of Social Science and Education Research(5). Search in Google Scholar

[33] Xinghong Liu & Fei Zhu.(2023).Research on Influencing Factors of Curriculum Ideological and Political Teaching Effect under Mixed Teaching Mode. International Journal of Educational Science and Theory(12),12-14. Search in Google Scholar

[34] JunWen. (2023).Discussion and Practice of Online and Offline Mixed Teaching Reform of Advertising Art Design Major in Open Education. Journal of Contemporary Educational Research(11),97-104. Search in Google Scholar

[35] Honghao Liu, Liang Zhang, Jing Hu & Tao Song.(2023).Practical Application of Mixed Teaching Mode in the Course of Graphic and Image Processing. Frontiers in Educational Research(25). Search in Google Scholar