Students’ developmental skills, including critical thinking skills, problem-solving skills, creativity, metacognitive skills, communication skills-collaboration, digital literacy-technology are integrated into current issues discussed at the 21st-century skills. Utilization of digital technology as media and learning resources reflects a transition of X generation to Y generation learners. The use of digital technology in learning can be an excellent opportunity to improve the 21st-century skills, particularly in the development of scientific communication skills in learning physics. This study employed 3D Page-Flipped Worksheet on impulse and momentum to improve students’ scientific communication skills. This research belongs to a developmental study with 4D development model covering Define, Design, Develop, and Disseminate. The subjects were students senior high school grade X in Yogyakarta. The results showed that 72.5% of students had excellent verbal communication skills, and 65.6% had good written communication skills. Based on the results, the use of 3D Page-Flipped Worksheet is successful in constructing the students’ understanding and communication skills, both oral and written.

3D Page-Flipped, scientific communication, 21st-century skill, technology in education

Ainsworth, S., Prain, V., & Tytler, R. (2011). Drawing to Learn in Science. Science, 333(6046), 1096-1097.

Arief, M. K., Handayani, L., & Dwijananti, P. (2012). Identifikasi Kesulitan Belajar Fisika Pada Siswa RSBI: Studi Kasus Di RSMABI Se Kota Semarang. UPEJ Unnes Physics Education Journal, 1(2), 5-10.

Azizah, R., Yuliati, L., & Latifah, E. (2015). Kesulitan Pemecahan Masalah Fisika pada Siswa SMA. Jurnal Penelitian Fisika dan Aplikasinya (JPFA), 5(2), 44-50.

Bakri, M. A. (2016). Studi Awal Implementasi Internet of Things pada Bidang Pendidikan. JREC (Journal of Electrical and Electronics), 4(1), 18-23.

Divan, A., & Mason, S. (2016). A Programme-Wide Training Framework to Facilitate Scientific Communication Skills Development amongst Biological Sciences Masters Students. Journal of Further and Higher Education, 40(4), 543-567.

Fathurohman, A. (2014). Analogi dalam Pengajaran Fisika. Jurnal Inovasi dan Pembelajaran Fisika, 1(1), 74-77.

Fikri, K., & Susilo, W. (2012). Penerapan Pembelajaran Fisika Dengan Analogi untuk Meningkatkan Hasil Belajar Siswa SMA. UPEJ Unnes Physics Education Journal, 1(2), 1-4.

Fischhoff, B. (2013). The Sciences of Science Communication. Proceedings of the National Academy of Sciences, 110(Supplement 3), 14033-14039.

Frye, E. M., Trathen, W., & Koppenhaver, D. A. (2010). Internet Workshop and Blog Publishing: Meeting Student (and Teacher) Learning Needs to Achieve Best Practice in the Twenty-First-Century Social Studies Classroom. The Social Studies, 101(2), 46-53.

Greenstein, L. M. (2012). Assessing 21st Century Skills: A Guide to Evaluating Mastery and Authentic Learning. Corwin Press.

Howard, S. K., Ma, J., & Yang, J. (2016). Student Rules: Exploring Patterns of Students’ Computer-Efficacy and Engagement with Digital Technologies in Learning. Computers & Education, 101(2016), 29-42.

Hubber, P., Tytler, R., & Haslam, F. (2010). Teaching and Learning about Force with a Representational Focus: Pedagogy and Teacher Change. Research in Science Education, 40(1), 5-28.

Ismet. (2013). Impact of Multiple Representations-Based Mechanics Learning on Prospective Physics Teachers’ Spatial Intelligence. Jurnal Pendidikan Fisika Indonesia-Indonesian Journal of Physics Education, 9(2), 132-143.

Khlaisang, J., & Koraneekij, P. (2019). Open Online Assessment Management System Platform and Instrument to Enhance the Information, Media, and ICT Literacy Skills of 21 st Century Learners. International Journal of Emerging Technologies in Learning, 14(7), 111-127.

Kim, J., & Lee, W. (2013). Meanings of Criteria and Norms: Analyses and Comparisons of ICT Literacy Competencies of Middle School Students. Computers & Education, 64(2013), 81-94.

Kulsum, U., & Nugroho, S. E. (2014). Penerapan Model Pembelajaran Cooperative Problem Solving untuk Meningkatkan Kemampuan Pemahaman Konsep dan Komunikasi Ilmiah Siswa pada Mata Pelajaran Fisika. UPEJ Unnes Physics Education Journal, 3(2), 73-78.

Lau, W. W., & Yuen, A. H. (2014). Developing and Validating of a Perceived ICT Literacy Scale for Junior Secondary School Students: Pedagogical and Educational Contributions. Computers & Education, 78(2014), 1-9.

Bingimlas, K. A. (2009). Barriers to the Successful Integration of ICT in Teaching and Learning Environments: A Review of the Literature. Eurasia Journal of Mathematics, Science & Technology Education, 5(3), 235-245.

McKinnon, M., & Vos, J. (2015). Engagement as a Threshold Concept for Science Education And Science Communication. International Journal of Science Education, Part B, 5(4), 297-318.

Nitz, S., Prechtl, H., & Nerdel, C. (2014). Survey of Classroom Use of Representations: Development, Field Test and Multilevel Analysis. Learning Environments Research, 17(3), 401-422.

Oktaviani, A. N., & Nugroho, S. E. (2015). Penerapan Model Creative Problem Solving pada Pembelajaran Kalor untuk meningkatkan Pemahaman Konsep dan Keterampilan Komunikasi. UPEJ Unnes Physics Education Journal, 4(1), 26-31.

Ugur, G., Dilber, R., Senpolat, Y., & Duzgun, B. (2012). The Effects of Analogy on Students’ Understanding of Direct Current Circuits and Attitudes towards Physics Lessons. European journal of educational research, 1(3), 211-223.

Rau, M. A., & Matthews, P. G. (2017). How to Make ‘More’ Better? Principles for Effective Use of Multiple Representations to Enhance Students’ Learning About Fractions. ZDM, 49(4), 531-544.

Rau, M. A., Aleven, V., Rummel, N., & Pardos, Z. (2014). How Should Intelligent Tutoring Systems Sequence Multiple Graphical Representations of Fractions? A Multi-Methods Study. International Journal of Artificial Intelligence in Education, 24(2), 125-161.

Sadiman, Arief, S., & Rahardjo, R. (2010). Understanding Media Education, Development, and Utilization. Jakarta: Rajawali Press.

Prahani, B. K., Limatahu, I., Winata, S. W., Yuanita, L., & Nur, M. (2016). Effectiveness of Physics Learning Material through Guided Inquiry Model to Improve Student’s Problem Solving Skills Based on Multiple Representation. International Journal of Education and Research, 4(12), 231-244.

Thiagarajan, S., Semmel, D. S., & Semmel, M. I. (1974). Instructional Development for Training Teachers of Exceptional Children Leadership Training Institute. Special Education.

Usrotin, D., & Nugroho, S. E. (2013). Penerapan Pembelajaran Melalui Kegiatan Laboratorium Inkuiri Terbimbing untuk Meningkatkan Kemampuan Pemecahan Masalah, Berkomunikasi, Dan Bekerjasama. UPEJ Unnes Physics Education Journal, 2(3), 68-73.

Waldrip, B., Prain, V., & Sellings, P. (2013). Explaining Newton’s Laws of Motion: Using Student Reasoning through Representations to Develop Conceptual Understanding. Instructional Science, 41(1), 165-189.

Wijayanti, P. I., & Hindarto, N. (2010). Eksplorasi Kesulitan Belajar Siswa pada Pokok Bahasan Cahaya dan Upaya Peningkatan Hasil Belajar melalui Pembelajaran Inkuiri Terbimbing. Jurnal Pendidikan Fisika Indonesia, 6(1), 1-5.

Yusuf, P. M. (2010). Komunikasi dan Instruksional Teori dan Praktek. Jakarta: Bumi Aksara.