Mathematical critical thinking skills in mathematics learning is an ability that needs to be mastered by every student in order to support students in the learning process. The purpose of this study was to analyzing the influence and interaction of the ARCS model and learning motivation on students' mathematical critical thinking skills. This research is a quasi-experimental design using cluster random sampling as a sampling technique. The data collection technique used an essay test to determine MCT and a questionnaire to see motivation. The data analysis technique used the normality test, homogeneity, and two-way ANOVA. The results have shown that there is an effect of the ARCS learning model on students' mathematical critical thinking ability, there is no influence of learning motivation on mathematical critical thinking skills, and there is no interaction between ARCS model learning and motivation towards mathematical critical thinking ability. Therefore, the ARCS model can be solution to fostering of mathematical critical thinking abilities. 

Afdarni, V. (2018). Validity Of Learning Devices Based On ARCS Model To Improve Mathematical Critical Thinking Ability. 2nd International Conference on Mathematics and Mathematics Education 2018 (ICM2E 2018).

Alhazbi, S. (2015). ARCS-based tactics to improve students’ motivation in computer programming course. 2015 10th International Conference on Computer Science & Education (ICCSE), 317–321.

Alper, A. (2010). Critical thinking disposition of pre-service teachers. Egitim ve Bilim, 35(158), 14.

Al‐Zahrani, A. M. (2015). From passive to active: The impact of the flipped classroom through social learning platforms on higher education students’ creative thinking. British Journal of Educational Technology, 46(6), 1133–1148.

Ampountolas, A., Shaw, G., & James, S. (2019). Active learning to improve self-confidence and decision-making skills through the use of hotel simulation. Journal of Hospitality & Tourism Education, 31(3), 125–138.

Asfar, A. M. I. T., & Asfar, A. M. I. A. (2020). Learning Design Based on Local Wisdom Maddawa-dawa, Mammanu-manu and Mappettuada. JTAM (Jurnal Teori Dan Aplikasi Matematika), 4(2), 214–223.

Aşıksoy, G., & Özdamlı, F. (2016). Flipped Classroom adapted to the ARCS Model of Motivation and applied to a Physics Course. Eurasia Journal of Mathematics, Science and Technology Education, 12(6), 1589–1603.

Barnhart, T., & van Es, E. (2015). Studying teacher noticing: Examining the relationship among pre-service science teachers’ ability to attend, analyze and respond to student thinking. Teaching and Teacher Education, 45, 83–93.

Benner, A. D., Boyle, A. E., & Sadler, S. (2016). Parental involvement and adolescents’ educational success: The roles of prior achievement and socioeconomic status. Journal of Youth and Adolescence, 45(6), 1053–1064.

Cho, M.-H., & Heron, M. L. (2015). Self-regulated learning: The role of motivation, emotion, and use of learning strategies in students’ learning experiences in a self-paced online mathematics course. Distance Education, 36(1), 80–99.

Dumitru, D. (2019). Creating meaning. The importance of Arts, Humanities and Culture for critical thinking development. Studies in Higher Education, 44(5), 870–879.

Fallah, V., Khosroabadi, S., & Usefi, H. (2015). Development of emotional quotient and spiritual quotient: The strategy of ethics development. International Letters of Social and Humanistic Sciences, 49, 43–52.

Firdaus, F. M. (2017). Improving Primary Students’ Mathematical Literacy through Problem Based Learning and Direct Instruction. Educational Research and Reviews, 12(4), 212–219.

Geiger, J. M., Cheung, J. R., Hanrahan, J. E., Lietz, C. A., & Carpenter, B. M. (2017). Increasing competency, self-confidence, and connectedness among foster care alumni entering a 4-year university: Findings from an early-start program. Journal of Social Service Research, 43(5), 566–579.

Guo, J., Marsh, H. W., Parker, P. D., Morin, A. J., & Yeung, A. S. (2015). Expectancy-value in mathematics, gender and socioeconomic background as predictors of achievement and aspirations: A multi-cohort study. Learning and Individual Differences, 37, 161–168.

Hartinah, S., Suherman, S., Syazali, M., Efendi, H., Junaidi, R., Jermsittiparsert, K., & Umam, R. (2019). Probing-prompting based on ethnomathematics learning model: The effect on mathematical communication skill. Journal for the Education of Gifted Young Scientists, 7(4), 799–814.

Hayward, M. D., Hummer, R. A., & Sasson, I. (2015). Trends and group differences in the association between educational attainment and US adult mortality: Implications for understanding education’s causal influence. Social Science & Medicine, 127, 8–18.

Holmes, V.-L., & Hwang, Y. (2016). Exploring the effects of project-based learning in secondary mathematics education. The Journal of Educational Research, 109(5), 449–463.

Huda, S., Rinaldi, A., Suherman, S., Sugiharta, I., Astuti, D. W., Fatimah, O., & Prasetiyo, A. E. (2019). Understanding of Mathematical Concepts in the Linear Equation with Two Variables: Impact of E-Learning and Blended Learning Using Google Classroom. Al-Jabar: Jurnal Pendidikan Matematika, 10(2), 261–270.

Ismail, N. S., Harun, J., Zakaria, M. A. Z. M., & Salleh, S. M. (2018). The effect of Mobile problem-based learning application DicScience PBL on students’ critical thinking. Thinking Skills and Creativity, 28, 177–195.

Jungert, T., Van den Broeck, A., Schreurs, B., & Osterman, U. (2018). How colleagues can support each other’s needs and motivation: An intervention on employee work motivation. Applied Psychology, 67(1), 3–29.

Keller, J. M. (2016). Motivation, learning, and technology: Applying the ARCS-V motivation model. Participatory Educational Research, 3(2), 1–15.

Knievel, I., Lindmeier, A. M., & Heinze, A. (2015). Beyond knowledge: Measuring primary teachers’ subject-specific competences in and for teaching mathematics with items based on video vignettes. International Journal of Science and Mathematics Education, 13(2), 309–329.

Komarudin, K., Suherman, S., Puspita, L., Arrafiansyah, R., & Hasanah, U. (2020). Program course lab 2.4 mathematics learning media for increasing of creativity domain at Higher Order Thinking Skills (HOTS). Journal of Gifted Education and Creativity, 7(3), 131–136.

Komarudin, Pranata, D., Nurhasanah, U., & Suherman. (2020). Developing Islamic-Friendly Android Mobile Apps for Understanding Mathematical Concepts. 1st Raden Intan International Conference on Muslim Societies and Social Sciences (RIICMuSSS 2019), 110–117.

Kraft, M. A., Marinell, W. H., & Shen-Wei Yee, D. (2016). School organizational contexts, teacher turnover, and student achievement: Evidence from panel data. American Educational Research Journal, 53(5), 1411–1449.

Ku, K. Y. (2009). Assessing students’ critical thinking performance: Urging for measurements using multi-response format. Thinking Skills and Creativity, 4(1), 70–76.

Kurniati, K., Kusumah, Y. S., Sabandar, J., & Herman, T. (2015). Mathematical critical thinking ability through contextual teaching and learning approach. Journal on Mathematics Education, 6(1), 53–62.

Kurt, P. Y., & Keçik, İ. (2017). The effects of arcs motivational model on student motivation to learn English. European Journal of Foreign Language Teaching.

LAÇİNBAY, K., & YILMAZ, M. (2020). Görsel Sanatlar Ders Materyali Geliştirme Sürecinde ARCS Motivasyon Modelinin Kullanımı. Kastamonu Eğitim Dergisi, 28(1), 468–481.

Lee, H., Parsons, D., Kwon, G., Kim, J., Petrova, K., Jeong, E., & Ryu, H. (2016). Cooperation begins: Encouraging critical thinking skills through cooperative reciprocity using a mobile learning game. Computers & Education, 97, 97–115.

Lee, L.-C., & Hao, K.-C. (2015). Designing and Evaluating Digital Game-Based Learning with the ARCS Motivation Model, Humor, and Animation: International Journal of Technology and Human Interaction, 11(2), 80–95. https://doi.org/10.4018/ijthi.2015040105

Lemberger, M. E., Selig, J. P., Bowers, H., & Rogers, J. E. (2015). Effects of the Student Success Skills program on executive functioning skills, feelings of connectedness, and academic achievement in a predominantly Hispanic, low‐income middle school district. Journal of Counseling & Development, 93(1), 25–37.

Li, K., & Moore, D. R. (2018). Motivating students in massive open online courses (MOOCs) using the attention, relevance, confidence, satisfaction (arcs) model. Journal of Formative Design in Learning, 2(2), 102–113.

Malik, S. (2014). Effectiveness of ARCS Model of Motivational Design to Overcome Non Completion Rate of Students in Distance Education. Turkish Online Journal of Distance Education, 15(2), 194–200.

Marin, L. M., & Halpern, D. F. (2011). Pedagogy for developing critical thinking in adolescents: Explicit instruction produces greatest gains. Thinking Skills and Creativity, 6(1), 1–13.

Milman, N. B., & Wessmiller, J. (2016). Motivating the online learner using Keller’s ARCS model. Distance Learning, 13(2), 67.

Munifah, M., Syamsul, H., Ulfi Dina, H., Subandi, S., Muhamad, S., & Rofiqul, U. (2019). The Use of Management Strategies to Attract the Public’s Interest in Pesantren: A New Model for Pesantren Dynamics Study. International Journal of Innovation, Creativity and Change, 8(8), 263–283.

Novotná, J., Eisenmann, P., Přibyl, J., Ondrušová, J., & Břehovský, J. (2014). Problem solving in school mathematics based on heuristic strategies. Journal on Efficiency and Responsibility in Education and Science, 7(1), 1–6.

Pratama, R. W., Sudiyanto, & Riyadi. (2019). The Development Of Attention, Relevance, Confidence, And Satisfaction (ARCS) Model Based on Active Learning to Improve Students’learning Motivation. Al-Jabar: Jurnal Pendidikan Matematika, 10(1), 59–66.

Reddy, M., & Panacharoensawad, B. (2017). Students Problem-Solving Difficulties and Implications in Physics: An Empirical Study on Influencing Factors. Journal of Education and Practice, 8(14), 59–62.

Reynolds, K. M., Roberts, L. M., & Hauck, J. (2017). Exploring motivation: Integrating the ARCS model with instruction. Reference Services Review.

Seventika, S. Y., Sukestiyarno, Y. L., & Mariani, S. (2018). Critical thinking analysis based on Facione (2015)-Angelo (1995) logical mathematics material of vocational high school (VHS). Journal of Physics: Conference Series, 983(1), 012067.

Siagan, M. V., Saragih, S., & Sinaga, B. (2019). Development of Learning Materials Oriented on Problem-Based Learning Model to Improve Students’ Mathematical Problem Solving Ability and Metacognition Ability. International Electronic Journal of Mathematics Education, 14(2), 331–340.

Suherman, S, Komarudin, K., Rosyid, A., Aryanita, S., Asriyanto, D., Aradika Putra, T., & Anggoro, T. (2018). Improving Trigonometry Concept Through STEM (Science, Technology, Engineering, And Mathematics) Learning. International Conference On Multidisciplinary Academic (ICMA), Indonesia.

Suherman, S, Prananda, M. R., Proboningrum, D. I., Pratama, E. R., & Laksono, P. (2020). Improving higher order thinking skills (hots) with project based learning (pjbl) model assisted by geogebra. Journal of Physics: Conference Series, 1467(1), 012027.

Surya, E., & Syahputra, E. (2017). Improving High-Level Thinking Skills by Development of Learning PBL Approach on the Learning Mathematics for Senior High School Students. International Education Studies, 10(8), 12–20.

Surya, Y. F., Marta, R., & Wijaya, T. T. (2020). Measurement of mathematics problems solving ability using problem based mathematics question. Journal of Physics: Conference Series, 1613(1), 012026.

Teo, T., & Milutinovic, V. (2015). Modelling the intention to use technology for teaching mathematics among pre-service teachers in Serbia. Australasian Journal of Educational Technology, 31(4).

Toner, J., & Moran, A. (2016). On the importance of critical thinking: A response to Wulf’s (2015) commentary. Psychology of Sport and Exercise, 22, 339–340.

Tsay, C. H.-H., Kofinas, A., & Luo, J. (2018). Enhancing student learning experience with technology-mediated gamification: An empirical study. Computers & Education, 121, 1–17.

Tseng, H. W., & Walsh Jr, E. J. (2016). Blended vs. Traditional course delivery: Comparing students’ motivation, learning outcomes, and preferences. Quarterly Review of Distance Education, 17(1).

Turel, Y. K., & Sanal, S. O. (2018). The effects of an ARCS based e-book on student’s achievement, motivation and anxiety. Computers & Education, 127, 130–140.

Ulandari, L., Amry, Z., & Saragih, S. (2019). Development of Learning Materials Based on Realistic Mathematics Education Approach to Improve Students’ Mathematical Problem Solving Ability and Self-Efficacy. International Electronic Journal of Mathematics Education, 14(2), 375–383.

Widyatiningtyas, R., Kusumah, Y. S., Sumarmo, U., & Sabandar, J. (2015). The Impact of Problem-Based Learning Approach to Senior High School Students’ Mathematics Critical Thinking Ability. Indonesian Mathematical Society Journal on Mathematics Education, 6(2), 30–38.

Ying, M.-H., & Yang, K.-T. (2013). A Game-based Learning System using the ARCS Model and Fuzzy Logic. JSW, 8(9), 2155–2162.

Yuliani, K., & Saragih, S. (2015). The Development of Learning Devices Based Guided Discovery Model to Improve Understanding Concept and Critical Thinking Mathematically Ability of Students at Islamic Junior High School of Medan. Journal of Education and Practice, 6(24), 116–128.

Zepeda, C. D., Martin, R. S., & Butler, A. C. (2020). Motivational strategies to engage learners in desirable difficulties. Journal of Applied Research in Memory and Cognition, 9(4), 468–474.

Zhang, W. (2017). Design a civil engineering micro-lecture platform based on the ARCS model perspective. International Journal of Emerging Technologies in Learning (IJET), 12(01), 107–118.