The Integration of Green Chemistry Principles into Small Scale Chemistry Practicum for Senior High School Students
Abstract
Implementation of Principles of Green Chemistry in teaching chemistry can become an essential approach to enhance students’ awareness of the environmental problem. In contrast with the goal of sustainability, chemistry practicum normally deals with chemicals and waste management which contribute to environmental problem. A shift toward more sustainable and economical experiments is essential to maintain the existence of the practicum in the senior high curriculum. Small Scale Chemistry (SSC) practicum is one of the approaches to promote sustainability in chemistry practicum by using smaller scale and safer apparatus. It is expected to produce less waste. It is also safer and more economical chemistry experiment. This research aims to study the integration of principles of green chemistry in chemistry practicum by using SSC experiment. This study investigates two main topics in senior high school chemistry subject: electrochemistry and acid-base indicator. This study has shown the practice of integration of the principles of green chemistry approach into senior high school chemistry practicum through SSC. The experiments demonstrated in this study enable us to integrate Principles of Green Chemistry in terms of preventing waste, using less hazardous chemical, and conducting safer experiments which can be implemented in senior high school chemistry practicum.
Keywords
Full Text:
PDFReferences
Abdullah, Mashita, Norita Mohamed, and Zurida Hj Ismail. “The Effect Of An Individualized Laboratory Approach Through Microscale Chemistry Experimentation On Students’ Understanding Of Chemistry Concepts, Motivation And Attitudes.†Chemistry Education Research and Practice 10.1 (2009): 53-61.
Ahmad, N. J., & Lah, Y. C. (2013). A Designed Teaching Sequence As A Tool To Improve Students’ Conceptual Understanding Of The Conductivity In The Electrolytic Cell. Asian Social Science, 9(2), 298.
Anastas, P. T., & Warner, J. C. (1998). Principles Of Green Chemistry. Green Chemistry: Theory and Practice. Oxford University Press: New York
Andraos, J., & Dicks, A. P. (2012). Green Chemistry Teaching In Higher Education: A Review Of Effective Practices. Chemistry Education Research and Practice, 13(2), 69-79.
Biswas, N., Ichikawa, M., Datta, A., Sato, Y. T., Yanagisawa, M., & Yoshikawa, K. (2012). Phase Separation In Crowded Micro-Spheroids: DNA–PEG System. Chemical Physics Letters, 539, 157-162.
Burmeister, M., & Eilks, I. (2013). Using Participatory Action Research To Develop A Course Module On Education For Sustainable Development In Pre-Service Chemistry Teacher Education. CEPS journal, 3(1), 59-78.
Choi, I., Lee, J. Y., Lacroix, M., & Han, J. (2017). Intelligent pH indicator Film Composed Of Agar/Potato Starch And Anthocyanin Extracts From Purple Sweet Potato. Food Chemistry, 218, 122-128.
Dikmenli, M., Cardak, O. S., & Kiray, A. (2015). Misconceptions Sequencing The Chemical Processes In Daniell and Electrolysis Cells Amongst First-Year Science And Mathematics Education University Students Conceptos Alternativos De Los Estudiantes Sobre Los Procesos QuÃmicos En Las Células De Daniell Y De Electrólisis. European Journal of Physics, 6(2), 54-73.
Dittmar, J., Zowada, C., Yamashita, S., & Eilks, I. (2016). Molecular Gastronomy In The Chemistry Classroom. Science in School, 36, 52-55.
Dong, X., Wang, Y., & Xia, Y. (2014). Re-building Daniell Cell with a Li-ion exchange Film. Scientific reports, 4, 6916.
Duarte, R. C., Ribeiro, M. G. T., & Machado, A. A. (2017). Reaction Scale And Green Chemistry: Microscale Or Macroscale, Which Is Greener?. Journal of Chemical Education, 94(9), 1255-1264.
Eggen, P. O. (2010). Current Chemistry: Experiments and Practice in Electrochemistry Education (Philosophiae Doctor), Norwegian University of Science and Technology.
Gross, E. M. (2012). Green Chemistry And Sustainability: An Undergraduate Course For Science And Nonscience Majors. Journal of Chemical Education, 90(4), 429-431.
Haley, R. A., Ringo, J. M., Hopgood, H., Denlinger, K. L., Das, A., & Waddell, D. C. (2018). Graduate Student Designed and Delivered: An Upper-Level Online Course for Undergraduates in Green Chemistry and Sustainability. Journal of Chemical Education, 95(4), 560-569.
Hamidah, N., Prabawati, S., Fajriati, I., & Eilks, I. (2017). Incorporating Sustainability In Higher Chemistry Education In Indonesia Through Green Chemistry: Inspirations By Inquiring The Practice In A German University. International Journal of Physics and Chemistry Education, 9(1), 1-7.
Khattiyavong, P., Jarujamrus, P., Supasorn, S., & Kulsing, C. (2014). The Development Of Small Scale And Low-Cost Galvanic Cells As A Teaching Tool For Electrochemistry. Journal of Research Unit on Science, Technology and Environment for Learning, 5(2), 146-154.
Kennedy, S. A. (2015). Design Of A Dynamic Undergraduate Green Chemistry Course. Journal of Chemical Education, 93(4), 645-649.
Khalid, K. D. U., Idris, M. B., Muhammad, N. A., & Bala, A. (2015). Study Of Acid-Base Indicator Property Of Ethanolic Extract Of Nerium Indicum Flower. Bri. J. Of Pharma Res, 9(4), 1-4.
Khan, P. M. A., & Farooqui, M. (2011). Analytical Applications of Plant Extract as Natural pH Indicator: A Review. Journal of Advanced Scientific Research, 2(4), 8-16.
Listyarini, R. V. (2019). Promoting Sustainability in Undergraduate Program: Students’perception In Green Chemistry Course. International Journal of Indonesian Education and Teaching (IJIET), 3(1), 67-79.
Mafumiko, F., Voogt, J., & Van den Akker, J. (2013). Design And Evaluation Of Micro-Scale Chemistry Experimentation In Tanzanian Schools. Educational design research–Part B: Illustrative cases, 581-600.
Mitarlis, M., Azizah, U., & Yonata, B. (2018, February). Learning Design to Integrate Scientific Character Values with Green Chemistry Insight in Basic Chemistry Course. In 1st International Conference on Education Innovation (ICEI 2017). Atlantis Press.
Nurbaity, Rahmawati Y., & Ridwan A. (2016). Integration Green Chemistry Approach in Teacher Education Program for Developing Awareness of Environmental Sustainability. Paper presented at the ASEAN Comparative Education Research Network Conference.
Owens, T. L. (2017). Higher Education In The Sustainable Development Goals Framework. European Journal of Education, 52(4), 414-420.
Prietto, L., Mirapalhete, T. C., Pinto, V. Z., Hoffmann, J. F., Vanier, N. L., Lim, L. T., ... & da Rosa Zavareze, E. (2017). pH-sensitive Films Containing Anthocyanins Extracted From Black Bean Seed Coat And Red Cabbage. LWT, 80, 492-500.
Rojanarata, T., Sumran, K., Nateetaweewat, P., Winotapun, W., Sukpisit, S., Opanasopit, P., & Ngawhirunpat, T. (2011). Microscale Chemistry-Based Design Of Eco-Friendly, Reagent-Saving And Efficient Pharmaceutical Analysis: A Miniaturized Volhard’s Titration For The Assay Of Sodium Chloride. Talanta, 85(3), 1324-1329.
Sattsangi, P. D. (2010). A Microscale Approach To Chemical Kinetics In The General Chemistry Laboratory: The Potassium Iodide Hydrogen Peroxide Iodine-Clock Reaction. Journal of Chemical Education, 88(2), 184-188.
Sharma, P., Gupta, R., Roshan, S., Sahu, S., Tantuway, S., Shukla, A., & Garg, A. (2013). Plant Extracts as Acid Base Indicator: An Overview. Inventi Impact: Planta Activa.
Singh, M. M., Szafran, Z., & Pike, R. M. (1999). Microscale Chemistry And Green Chemistry: Complementary Pedagogies. Journal of Chemical Education, 76(12), 1684.
Supasorn, S. (2015). Grade 12 Students’ Conceptual Understanding And Mental Models Of Galvanic Cells Before And After Learning By Using Small-Scale Experiments In Conjunction With A Model Kit. Chemistry Education Research and Practice, 16(2), 393-407.
Tesfamariam, G., Lykknes, A., & Kvittingen, L. (2014). Small-Scale Chemistry For A Hands-On Approach To Chemistry Practical Work In Secondary Schools: Experiences From Ethiopia. African Journal of Chemical Education, 4(3), 48-94.
Tesfamariam, G. M., Lykknes, A., & Kvittingen, L. (2017). ‘Named Small but Doing Great’: An Investigation of Small-Scale Chemistry Experimentation for Effective Undergraduate Practical Work. International Journal of Science and Mathematics Education, 15(3), 393-410.
Timmer, B. J., Schaufelberger, F., Hammarberg, D., Franzén, J., Ramström, O., & Dinér, P. (2018). Simple and Effective Integration of Green Chemistry and Sustainability Education into an Existing Organic Chemistry Course. Journal of Chemical Education, 95(8), 1301-1306.
UNESCO. (2017). Education for Sustainable Development Goals Learning Objectives. 7, place de Fontenoy, 75352 Paris 07 SP, France.
Ural, E. (2016). The effect of guided-inquiry laboratory experiments on science education students’ chemistry laboratory attitudes, anxiety and achievement. Journal of Education and Training Studies, 4(4), 217-227.
Valavanidis, A., & Vlachogianni, T. (2013). Plant Polyphenols: Recent Advances In Epidemiological Research And Other Studies On Cancer Prevention. In Studies in Natural Products Chemistry (Vol. 39, pp. 269-295). Elsevier.
Vyas Arpita, D., Modi Dikhit, C., & Vijay, L. (2012). Screening and Development of Herbal Acid-Base pH Indicator from Traditional Flowers. Pharma Science Monitor, 3(4), 2211-2221.
Zakaria, Z., Latip, J., & Tantayanon, S. (2012). Organic Chemistry Practices For Undergraduates Using A Small Lab Kit. Procedia-Social and Be
Refbacks
- There are currently no refbacks.