Digital Problem-Based Worksheet with 3D Pageflip: An Effort to Address Concept Understanding Problems and Enhance Digital Literacy Skills
Abstract
This study aims to provide digital teaching materials in the form of problem-based worksheets with 3D PageFlip presentations that are valid, practical, and effective in overcoming conceptual understanding problems and enhancing digital literacy skills in high school students. The research approach employed was a mixed method based on Thiagarajan’s (1974) 4D development model, which consists of four stages: define, design, develop, and disseminate. Three experts conducted the validity test and a limited field test involving ten high school students. Furthermore, the large-scale field test was carried out at another high school with 60 students utilizing the static pretest-post-test design. Data for the study were gathered through observation, tests, and questionnaires. Qualitative data analysis was done descriptively using the percentage technique, while quantitative data was analyzed using statistical tests. According to the results, the problem-based digital worksheet with the 3D PageFlip display has an average content validity of 8.83 and an average construct validity of 8.91. It has been proven practical with a digital worksheet implementation rate of 89.39 and positive student responses. Conceptual understanding that occurs before learning can be overcome through images and videos embedded in digital worksheets. The difference in concept knowledge and digital literacy progress between the experimental and control groups demonstrates the usefulness of this teaching material. Thus, problem-based digital worksheet teaching materials with 3D PageFlip can overcome conceptual understanding problems and improve students’ digital literacy.
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Abdullah, A. H., Julius, E., Yann, T. Y., Mokhtar, M., & Abd Rahman, S. N. S. (2018). Using cooperative learning to overcome students’ misconceptions about fractions. NeuroQuantology, 16(11), 79–92.
Abdullah, N., Halim, L., & Zakaria, E. (2014). VStops: A thinking strategy and visual representation approach in mathematical word problem solving toward enhancing STEM literacy. Eurasia Journal of Mathematics, Science and Technology Education, 10(3), 165–174.
Agung, R., Prasetyo, A., Siti, D., Eka, K., & Ridwan, M. (2023). Digital puzzle worksheet for identifying metacognition level of students: A study of gender differences. European Journal of Educational Research, 12(2), 795–810.
Amalia, S. A., Suhendi, E., Kaniawati, I., Samsudin, A., Fratiwi, N. J., Hidayat, S. R., Zulfikar, A., Sholihat, F. N., Jubaedah, D. S., Setyadin, A. H., Purwanto, M. G., Muhaimin, M. H., Bhakti, S. S., & Afif, N. F. (2019). Diagnosis of Student’s Misconception on Momentum and Impulse Through Inquiry Learning with Computer Simulation (ILCS). Journal of Physics: Conference Series, 1204, 012073.
Amawa, I., Yerizon, Y., Sri, N., & Putra, R. T. (2019). Development of students’ worksheet based on APOS Theory approach to improve student achievement in learning system of linear equations. International Journal of Scientific Dan Technology Research, 8(4), 287–292.
Anderson, L. W., & Krathwohl, D. R. (2021). A taxonomy for learning, teaching, and assessing: A revision of Bloom’s taxonomy of educational objectives. Longman.
Andriati, R., bin Sansuwito, T., Ramuni, K., & Abdullah, B. F. (2022). Effectiveness of 3D Pageflip Professional electronic module to prevent urolithiasis recurrent among urolithiasis patients. Gaceta Medica de Caracas, 130(Supl 5), S1060–S1067.
Ariyana, N., & Putra, F. G. (2021). SiMaYang type II learning model assisted by Kahoot application: Its impact in improving student’s concept understanding based on apos theory. Online Learning In Educational Research, 1(1), Article 1.
Artayasa, I. P., Susilo, H., Lestari, U., & Indriwati, S. E. (2018). The effect of three levels of inquiry on the improvement of science concept understanding of elementary school teacher candidates. International Journal of Instruction, 11(2), 235–248.
Atasoy, Ş., & Ergin, S. (2017). The effect of concept cartoon-embedded worksheets on grade 9 students’ conceptual understanding of Newton’s Laws of Motion. Research in Science & Technological Education, 35(1), 58–73.
Atasoy, S., Kucuk, M., & Akdeniz, A. R. (2011). Remedying science student teachers’ misconceptions of force and motion using worksheets based on constructivist learning theory. Energy Education Science and Technology Part B: Social and Educational Studies, 3(4), 519–534.
Biney, S. K., Ali, C. A., & Adzifome, N. S. (2023). Errors and misconceptions in solving linear inequalities in one variable. Journal of Advanced Sciences and Mathematics Education, 3(1), 15–26.
Chan, B. S. K., Churchill, D., & Chiu, T. K. F. (2017). Digital literacy learning in higher education through digital storytelling approach. Journal of International Education Research (JIER), 13(1), 1–16.
Dewi, A. K., Slamet, S. Y., Atmojo, I. R. W., & Syawaludin, A. (2023). The influence of interactive digital worksheets based on level of inquiry towards science process skills in elementary school. Pegem Journal of Education and Instruction, 13(1), 251–258.
Diani, R., Anggraeni, Y. M., Fujiani, D., & Yuliani, E. (2023). The identification of senior high school students’ misconception on physics using the four-tier diagnostic test with certainty of response index. AIP Conference Proceedings, 020016.
Distrik, I. W., Ertikanto, C., & Sesunan, T. M. (2022). The practicality and effectiveness of the e-worksheet with creative inquiry based and HOTS oriented “3D PageFlip” for online learning. Jurnal Pembelajaran Fisika, 10(1), 1–20.
Distrik, I. W., & Saregar, A. (2022). The role of multiple-representation-based ‘real’ learning model in the development of students’ metacognitive and problem-solving abilities. Technium Soc. Sci. J., 34, 126.
Distrik, I. W., Supardi, Z. A. I., & Jatmiko, B. (2021). The effects of multiple representations-based learning in improving concept understanding and problem-solving ability. Journal of Physics: Conference Series, 1796(1), 12044.
Erman, E. (2017). Factors contributing to students’ misconceptions in learning covalent bonds. Journal of Research in Science Teaching, 54(4), 520–537.
Gilster, P. (1997). Digital Literacy. Wiley Computer Pub.
Hofer, S. I., Schumacher, R., Rubin, H., & Stern, E. (2018). Enhancing physics learning with cognitively activating instruction: A quasi-experimental classroom intervention study. Journal of Educational Psychology, 110(8), 1175–1191.
Ismail, A., Gumilar, S., Amalia, I. F., Bhakti, D. D., & Nugraha, I. (2019). Physics learning media-based augmented reality (AR) for electricity concepts. Journal of Physics: Conference Series, 1402(6), 066035.
Jammeh, A. L. J., Karegeya, C., & Ladage, S. (2023). Misconceptions on basic stoichiometry among the selected eleventh-grade students in the urban regions of the Gambia. Journal of Baltic Science Education, 22(2), 254–268.
Karpudewan, M., Treagust, D. F., Mocerino, M., Won, M., & Chandrasegaran, A. L. (2016). Investigating high school students’ understanding of chemical equilibrium concepts. The International Journal of Environmental and Science Education, 10(6), 845–863.
Kashyap, A. M. N., Sailaja, S. V., Krishna, B. M., & Vamseekiran, T. (2023). Optimizing problem-based learning in civil and electrical engineering: An in-depth study. Journal of Advanced Sciences and Mathematics Education, 3(1), 53–63.
Kolić-Vehovec, S., Pahljina-Reinić, R., & Rončević Zubković, B. (2022). Effects of collaboration and informing students about overconfidence on metacognitive judgment in conceptual learning. Metacognition and Learning, 17(1), 87–116.
Kurniawan, Y., Muliyani, R., & Nassim, S. (2019). Digital story conceptual change-oriented (DSCC) to reduce student misconceptions in physics. Jurnal Ilmiah Pendidikan Fisika Al-Biruni, 8(2), 207-216.
Maharani, L., Rahayu, D. I., Amaliah, E., Rahayu, R., & Saregar, A. (2019). Diagnostic test with four-tier in physics learning: case of misconception in Newton’s Law material. Journal of Physics: Conference Series, 1155, 012022.
Meltzer, D. E. (2002). The relationship between mathematics preparation and conceptual learning gains in physics: A possible “hidden variable” in diagnostic pretest scores. American Journal of Physics, 70(12), 1259–1268.
Mufit, F., Festiyed, F., Fauzan, A., & Lufri, L. (2023). The effect of cognitive conflict-based learning (CCBL) model on remediation of misconceptions. Journal of Turkish Science Education, 20(1), 26–49.
Mujasam, M., Allo, A. Y. T., & Ansaruddin, M. (2019). The effectiveness of experiment-based student worksheets with map concept in understanding the physics concepts of static fluid materials. Journal of Physics: Conference Series, 1157, 032023.
Mutlu, A. (2020). Evaluation of students’ scientific process skills through reflective worksheets in the inquiry-based learning environments. Reflective Practice, 21(2), 271–286.
Nurulsari, N., Viyanti, V., & Yassine, B. (2023). HOTS-Oriented student worksheets with blended learning: Improving students’ science process skills. Online Learning in Educational Research, 3(1), 47-58.
Okuboyejo, O. Y., Ewert, S., & Sanders, I. (2021). Goofs in the Class: Students’ Errors and Misconceptions When Learning Regular Expressions. 49th Annual Conference of the Southern African Computer Lecturers Association, SACLA 2020, 57–71.
Pohan, E. H. M., Fitriani, Rambe, A., & Ariaji, R. (2020). Minimizing misconception and improving student’s conceptual learning for motion and force concepts by student worksheet (LKS)-based of cels (combining experiments by laboratory simulation). Journal of Physics: Conference Series, 1477(4), 042060.
Ponjen, D., & Suparman. (2020). Student worksheets design to improve problem-solving ability with problem-based learning. International Journal of Scientific and Technology Research, 9(3), 4700–4705.
Pratama, A. S., & Widowati, A. (2022). Development of natural science e-student worksheet based on nos within guided inquiry-based learning for improving students’ digital literacy. AIP Conference Proceedings, 070007.
Priadi, M. A., Marpaung, R. R. T., & Fatmawati, Y. (2021). Problem-based learning model with Zoom breakout rooms application: Its impact on students’ scientific literacy. Online Learning In Educational Research, 1(2), 93–101.
Primanda, A., Distrik, I. W., & Abdurrahman, A. (2019). The impact of 7E learning cycle-based worksheets toward students’ conceptual understanding and problem-solving ability on Newton’s Law of Motion. Journal of Science Education, 2(19), 95–106.
Ramadhan, K. A., Hairun, Y., & Bani, A. (2020). The development of Hots-based student worksheets with discovery learning model. Universal Journal of Educational Research, 8(3), 888–894.
Ramlah Abadi, A. P., Aisyah, D. S., Lestari, K. E., & Yudhanegara, M. R. (2023). Digital Puzzle Worksheet for Identifying Metacognition Level of Students : European Journal of Educational Research, 12(2), 795–810.
Resbiantoro, G., Setiani, R., & Dwikoranto. (2022). A Review of Misconception in Physics: The Diagnosis, Causes, and Remediation: Research Article. Journal of Turkish Science Education, 19(2), 403–427.
Rozi, F. (2020). Electronic student worksheet design based on guided discovery learning to improve critical thinking ability. Journal of Advanced Research in Dynamical and Control Systems, 12(7), 502–510.
Sari, I., Karim, S., Saepuzaman, D., Ramalis, T., & Rusdiana, D. (2020). The development of model-based learning in introductory physics: The effectiveness of improving students understanding in heat and heat transfer. Proceedings of the Proceedings of the 7th Mathematics, Science, and Computer Science Education International Seminar, MSCEIS 2019, 12 October 2019, Bandung, West Java, Indonesia.
Sari, P. M., Herlina, K, & Abdurrahman, A. (2022). Online learning with multi-representation worksheets for oral and written communication skills on light-reflecting material. Online Learning in Educational Research, 2(1), 49-56.
Siong, L. C., Tyug, O. Y., Phang, F. A., & Pusppanathan, J. (2023). The use of concept cartoons in overcoming the misconception in electricity concepts. Participatory Educational Research, 10(1), 310–329.
Suherman, Rahmadani, N. A., Vidákovich, T., Mujib, Fitria, N., Sari Putri, N. I., Addarojat, M. R., & Priadi, M. (2021). SQ3R method assisted by ethnomathematics-oriented student worksheet: The impact of mathematical concepts understanding. Journal of Physics: Conference Series, 1796(1), 012059.
Sumarmi, S., Aliman, M., & Mutia, T. (2021). The effect of digital eco-learning in student worksheet flipbook to environmental project literacy and pedagogic competency. Journal of Technology and Science Education, 11(2), 357–370.
Supurwoko, Cari, Sarwanto, Sukarmin, Fauzi, A., Faradilla, L., & Dewi, T. S. (2017). Using computer simulation to improve high order thinking skills of physics teacher candidate students in Compton effect. Journal of Physics: Conference Series, 909, 012062.
Susilaningsih, E., & Aprilia, N. (2022). Dissemination of diagnostic three-tier multiple choice test instruments for misconceptions analysis of macroscopic, sub-microscopic, and symbolic students in chemical learning. AIP Conference Proceedings, 040008.
Suyono, & Sabtiawan, W. B. (2019). Reducing the misconception burdens of students with balanced visual-verbal learning style through the conceptual change strategy assisted by student worksheet. Journal of Science Education, 20(2), 85–98.
Syafina, B. P., & Suparman, S. (2019). Designing student worksheets To improve critical thinking ability based on problem-based learning. International Journal Of Scientific & Technology Research, 8(10), 1194–1199.
Thiagarajan, S. (1974). Instructional development for training teachers of exceptional children: A sourcebook. ERIC.
Tumanggor, A. M. R., Supahar, S., Ringo, E. S., & Harliadi, M. D. (2020). Detecting students’ misconceptions in simple harmonic motion concepts using four-tier diagnostic test instruments. Jurnal ilmiah pendidikan fisika Al-Biruni, 9(1), 21-31.
Umriani, F., Suparman, Hairun, Y., & Sari, D. P. (2020). Analysis and design of mathematics student worksheets based on PBL learning models to improve creative thinking. International Journal of Advanced Science and Technology, 29(7), 226–237.
Ussarn, A., Pimdee, P., & Kantathanawat, T. (2022). Needs assessment to promote the digital literacy among students in Thai community colleges. International Journal of Evaluation and Research in Education (IJERE), 11(3), 1278.
Wityanita, Djamas, D., & Yohandri. (2019). Validation of Physics student’s worksheet based on cognitive conflict strategy to minimize student’s misconception. Journal of Physics: Conference Series, 1185, 012112.
Wong, Y. Y., & Chuah, T. C. (2023). an Online Learning Tool for 5G Radio Access Network Dimensioning. Journal of Engineering Science and Technology, 18(3), 1670–1684.
Yerizon, Y., Armiati, A., Tasman, F., & Abdullah, B. (2019). Development of student worksheets based on m-apos approach with mind mapping to improve mathematical communication ability of grade VII students of middle school. International Journal of Scientific Dan Technology Research, 8(6), 352–356.
Yerizon, Y., Arnawa, I. M., Fitriani, N., & Tajudin, N. M. (2022). Constructing calculus concepts through worksheet-based problem-based learning assisted by GeoGebra Software. HighTech and Innovation Journal, 3(3), 282–296.
Yuningsih, Y. Y. A., Farida, F., & Pratiwi, D. D. (2021). Schoology-based e-learning: The impact on concepts understanding and mathematical communication abilities. Online Learning in Educational Research, 1(2), 81-93.
Yustina, Y., Mahadi, I., Daryanes, F., Alimin, E., & Nengsih, B. (2022). The effect of problem-based learning through blended learning on digital literacy of eleventh-grade students on excretory system material. Jurnal Pendidikan IPA Indonesia, 11(4), 567–577.
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