DEVELOPMENT OF CCDSR TEACHING MODEL TO IMPROVE SCIENCE PROCESS SKILLS OF PRE-SERVICE PHYSICS TEACHERS-Reference-Cited by-同舟云学术

DEVELOPMENT OF CCDSR TEACHING MODEL TO IMPROVE SCIENCE PROCESS SKILLS OF PRE-SERVICE PHYSICS TEACHERS

Published:2018-10-15 Issue:5 Volume:17 Page:812-827
ISSN:2538-7138
Container-title:Journal of Baltic Science Education
language:en
Short-container-title:JBSE

Author:

Limatahu Iqbal¹,Wasis Wasis²,Sutoyo Suyatno²,Prahani Binar Kurnia³

Affiliation:

1. University of Khairun, Indonesia

2. State University of Surabaya, Indonesia

3. State Islamic University of Sunan Ampel, Indonesia

Abstract

CCDSR teaching model is physics teaching with the scientific activities by design to improve science process skills and its learning. This research was conducted to develop and produce a qualified CCDSR teaching model to improve the science process skills of pre-service physics teachers. The analysis of CCDSR teaching models’ quality was done by using mean validity score, Cronbach’s coefficient alpha, Paired t-test, N-gain, and ANOVA test. The results showed that the CCDSR teaching model was proved to be qualified (valid, practical, and effective) to improve the science process skills of pre-service physics teachers. Based on response results was that the CCDSR teaching model can improve the learning skills of science process skills (designing and implementing science process skills learning) owned by pre-service physics teachers. The implication of this research is that the CCDSR teaching model can be an innovative solution to improve science process skills of pre-service physics teachers. Keywords: CCDSR teaching model, research and development, pre-service physics teachers, science process skills.

Publisher

Scientia Socialis Ltd

Subject

Education

Reference59 articles.

1. Alkan, F. (2016). Experiential learning: Its effects on achievement and scientific process skills. Journal of Turkish Science Education, 13 (2), 15-26.

2. Arabacioglu, S., & Unver, A. O. (2016). Supporting inquiry-based laboratory practices with mobile learning to enhance students’ process skills in science education. Journal of Baltic Science Education, 15 (2), 216-230.

3. Arends, R. I. (2012). Learning to teach. New York: Mc. Graw-Hill Companies.

4. Astutik, S., & Prahani, B.K. (2018). The practicality and effectiveness of collaborative creativity learning (CCL) model by using phet simulation to increase students’ scientific creativity. International Journal of Instruction, 11 (4), 1-15.

5. Aydin, A. (2013). Representation of science process skills in the chemistry curricula for grades 10, 11 and 12 Turkey. International Journal of Education and Practice, 1 (5), 51-63.

Cited by 12 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. A case study of how digital competencies affect Pre-Service Physics Teachers’ Professional growth: Realizing SDG 4;E3S Web of Conferences;2024

2. Improving the competence of chemistry teachers in developing the minimum competency assessment (MCA);COMPUTATIONAL INTELLIGENCE AND NETWORK SECURITY;2023

3. Improving Student's Critical Thinking Skills and Self Efficacy Through Implementation of Integrated Guided Inquiry Model with Science, Technology, Engineering and Mathematics (STEM);Advances in Social Science, Education and Humanities Research;2023

4. Improving the Competence of Chemistry Teachers in Developing the Assessment Instrument Based on Higher Order Thinking Skills (HOTS);Advances in Social Science, Education and Humanities Research;2023

5. The Effect of Rode Learning Model on Enhancing Students Communication Skills;Studies in Learning and Teaching;2022-12-06