Abstract
If our chosen aim in science education is to be inclusive and to improve students’ learning achievements, then we must identify teaching methodologies that are appropriate for teaching and learning specific knowledge. Karagiorgi and Symeo (2005) remind us that instructional designers are thus challenged to translate the philosophy of constructivism into current practice. Thus, research in science education must focus on evaluating intervention programs which ensure the effective construction of knowledge and development of competencies. The present study reports the elaboration, application and evaluation of a problem-based learning (PBL) program with the aim of examining its effectiveness with students learning Environmental Education. Prior research on both PBL and Environmental Education (EE) was conducted within the context of science education so as to elaborate and construct the intervention program. Findings from these studies indicated both the PBL methodology and EE as helpful for teachers and students. PBL methodology has been adopted in this study since it is logically incorporated in a constructivism philosophy application (Hendry et al. 1999) and it was expected that this approach would assist students towards achieving a specific set of competencies (Engel 1997). On the other hand, EE has evolved at a rapid pace within many countries in the new millennium (Hart 2007), unlike any other educational area. However, many authors still appear to believe that schools are failing to prepare students adequately in EE (Walsche 2008; Winter 2007). The following section describes the research that was conducted in both areas so as to devise the intervention program.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Barrows, H. S., & Tamblyn, R. (1980). Problem based learning: An approach to medical education. New York: Springer.
Belbin, R. M. (1993). Teams roles at work. Oxford: Butterworth-Heinemann.
Belt, S. T., Evans, E. H., Mcreddy, T., Overton, T. L., & Summerfield, S. (2002). A problem-based learning approach to analytical and applied chemistry. University Chemistry Education, 6, 65–72.
Boud, D., & Feleti, G. (1997). Changins problem-based learning. Introduction to second ediion. In D. Boud & G. Felletti (Eds.), The challenge of problem-based learning (pp. 1–14). Londres: Kogan Page.
Boud, D., & Lee, A. (2005). ‘Peer Learning’ as pedagogical discourse for research education. Studies in Higher Education, 30(5), 501–516.
BouJaoude, S. (1992). The relationship between students’ learning strategies and the change in their misunderstandings during a high school chemistry course. Journal of Research in Science Teaching, 29(7), 687–699.
Cartney, P., & Rouse, A. (2006). The emotional impact of learning in small groups: Highlighting the impact on student progression and retention. Teaching in Higher Education, 11(1), 79–91.
Chandrasegara, A. L., Treagust, D. F., & Mocerino, M. (2008). An evaluation of teaching intervention to promote students’ ability to use multiple levels of representation when describing and explaining chemical reactions. Research in Science Education, 38, 237–248.
Chang, C. (2002). An exploratory study on students’ problem-solving ability in earth-science. International Journal of Science Education, 24(5), 441–451.
Cusick, J. (2008). Study abroad in support of education for sustainability: A New Zealland case study. Environment, Development and Sustainability. Retrieved February 26, 2009, from http://www.springerlink.com/content/gg4322473400q953/
Dahglgren, M. A., Castensson, R., & Dahglgren, L. (1998). PBL from the teachers' perspective: Conceptions of the tutor's role within problem based learning. Higher Education, 36, 437–447.
Derbentseva, N., Safayeni, F., & Cañas, A. J. (2007). Concept maps: Experiments on dynamic thinking. Journal of Research in Science Teaching, 44(3), 448–465.
Dods, R. F. (1996). A problem-based learning design for teaching biochemistry. Journal of Chemical Education, 73, 225–228.
Dogru, M. (2008). The Application of Problem Solving Method on Science Teacher Traineess on the Solution of the Environmental Problems. Journal of Environmental & Science Education, 381, 9–18.
Dyball, M. C., Reid, A., Ross, P., & Schoch, H. (2007). Evaluating assessed group-work in a second-year management accounting subject. Accounting Education, 16(2), 145–162.
Engel, C. E. (1997). Not just a method but a way of learning. In D. Boud & G. I. Feleti (Eds.), The challenge of problem-based learning (pp. 17–27). New York: St. Martin’s Press.
Enghag, M., Gustafsson, P., & Jonsson, G. (2007). From everyday life experiences to physic understanding occurring in small group work with context rich problems during introductory physics work at university. Research in Science Education, 37, 449–467.
Freeman, L. A., & Jessup, L. M. (2004). The power and benefits on concept mapping: Measuring use, usefulness, ease of use, and satisfaction. International Journal of Science Education, 26(2), 151–169.
Fuller, I. C. (2006). What is the value of fieldwork? Answers from New Zealand using two Contrasting undergraduate physical geography field trips. New Zealand Geographer, 62, 215–220.
Goodnough, K., & Cahsion, M. (2003). Fostering inquiry through problem-based learning. Science Teacher (Normal III), 79(9), 21–25.
Gürses, A., Acikyildiz, M., Doar, Ç., & Sözbilir, M. (2007). Na investigation of effectiveness of problem-based learning at physical chemistry laboratory. Research in Science and Technological Education, 78, 1126–1130.
Hart, P. (2007). Environmental education. In S. Abell & N. Lederman (Eds.), Handbook on research in science education (pp. 689–728). New Jersey: Lawrence Erlbaum Associated, Inc.
Hendry, G. D., Frommer, M., & Walker, R. A. (1999). Constructivism and problem based learning. Journal of Further and Higher Education, 23(3), 359–371.
Huffman, D., Lawernz, F., & Minger, M. (1997). Within-class analysis of ninth-grade science students’ perceptions of the learning environment. Journal of Research in Science Teaching, 34(8), 791–804.
Íngeç, S. K. (2009). Analysing concept map as an assesment tool in teaching physics and comparasion with the achievent tests. International Journal of Science Education, 31(14), 1897–1915.
Jeronen, E., Jeronen, J., & Raustia, H. (2009). Environmental education in Finland — a case study of environemntal education in nature schools. International Journal of Environmental & Science Education, 4(1), 1–23.
Karagiorgi, Y., & Symeo, L. (2005). Translating constructivism into instructional design: Potential and limitations. Educational Technology & Society, 8(1), 17–27.
Killacky, J., & Hulse-Killacky, D. (2004). Group work is not justo for the group class anumore: Taching generic group competency skills across the counsellor education curriculum. Journal for Specialists in Group Work, 29(1), 87–96.
Lambros, A. (2004). Problem based learning in middle and high school classrooms. A teacher’s guide to implementation. California: Corwin Press.
Lima, A., Vasconcelos, C., Félix, N., Barros, J., & Mendonça, A. (2010). Field trip activity in an ancient gold mine: scientific literacy in informal education. Public Understanding of Science, 19(3), 332–334.
NEETF (2000). Environment-based Education: Creating high performance schools and students. Washington D. C: The National Environmental Education Teaching Foundations.
Neville, A. J. (1999). The problem-based learning tutor: Teacher? Facilitator? Evaluator? Medical Teacher, 21(4), 393–401.
OECD (2008). The OECD work on competencies for Education for Sustainable Development (ESD). Retrived May 4, 2010 from http://www.oecd.org.
Palmer, J. A. (1998). Environmental education in the 21st century: Theory, practice, progress and promise. London: Routledge.
Parlo, A. T., & Butler, M. B. (2007). Impediments to environmental education instruction in the classroom: A post-workshop inquiry. Journal of Environmental & Science Education, 2(1), 32–37.
Perrenoud, P. (1995). Enseigner des savoirs ou développer des compétences: Lécole entre deux paradigmes. In: A. Bentolila (Org), Savoir ou savoir faire (pp. 73–141). Nathan: Paris.
Prince, K., Van Eijs, P., Boshuizen, H., Vleuten, C., & Scherpbier, A. (2005). General competencies of problem-based learning (PBL) and non-PBL graduates. Medical Education, 39, 394–401.
Reigosa, C., & Jiménez-Aleixandre, M. (2007). Scaffolded problem-solving in physics and chemistry laboratory: Difficulties hindering Students’ assumption of responsability. International Journal of Science Education, 29(3), 307–329.
Rickinson, M. (2001). Learners and learning in environmental education: A critical review of the evidence. Environmental Educational Research, 7(3), 207–320.
Safayeni, F., Derbentseva, N., & Cañas, A. J. (2005). A theoretical note on concepts and the need for cyclic concept maps. Journal of Research in Science Teaching, 42, 741–766.
Saunders, W. L., & Shepardson, D. (1987). A comparison of concrete and formal science instruction upon science achievement and reasoning ability of sixth grade students. Journal of Research in Science Teaching, 24, 39–51.
Schmidt, H., & Moust, J. (1995). What makes a tutor effective? A structural-equations modelling approach to learning in problem-based curricula. Academic Medicine, 70(8), 708–714.
Simons, P. R. J. (1997). Definition and theories of active learning. In D. Stern & G. L. Huber (Eds.), Active learning for students and teachers. Reports from eight countries (pp. 19–39). Frankfurt am Main: Peter Lang.
Slavin, R. E. (1997). Co-operative learning among students. In D. Stern & G. L. Hubber (Eds.), Active learning for students and teachers. Reports from eight countries (pp. 159–173). Frankfurt am Main: Peter Lang.
Smyth, J., Blackmore, C., & Harvey, T. (1997). Education for sustainability of the united nations: Making progress. The Environmentalist, 17, 173–179.
Strachan, I. B., & Wilcox, S. (1996). Peer and self assessment of group work developing an effective response to increased enrolment in a third-years course in microclimatology. Journal of Geography in Higher Education, 20(3), 343–353.
Tarhan, L., Ayar-Kayali, H., Urek, R. O., & Azar, B. (2008). Problem-based learning in 9th grade chemistry class: Intermolecular forces. Research in Science Education, 38, 285–300.
Taylor, J. A., & McDonald, C. (2007). Writing in groups as a tool for non-routine problem solving in first year university mathematics. International Journal of Mathematics Education in Science, 38(5), 639–655.
Van Loon, A. J. (2008). Geological education of the future. Earth Science Reviews, 86, 247–254.
Walsche, N. (2008). Understanding students’ conceptions of sustainability. Environmental Education Research, 14(5), 537–558.
White, H. B. (2001). A PBL course that uses research articles as problems. In B. J. Duch, S. E. Groh, & D. E. Allen (Eds.), A practical “how to” for teaching undergraduate course in any discipline: The power of problem-based learning (pp. 131–141). Sterling: Stylus Publishing.
Winter, C. (2007). Education for sustainable development and the secondary curriculum in English schools: Rhetoric or reality? Cambridge Journal of Education, 37(3), 337–354.
Wong, K. H., & Day, J. R. (2008). A comparative study of problem-based and lecture-based learning in junior secondary school science. Research in Science Education. Retrieved February 26, 2009, from http://www.springerlink.com/content/l7511p7241n221j1
Woods, D. (Ed.). (2000). Problem-based learning: How to gain the most from PBL. Hamilton: McMaster University, The Bookstore.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Vasconcelos, C. Teaching Environmental Education through PBL: Evaluation of a Teaching Intervention Program. Res Sci Educ 42, 219–232 (2012). https://doi.org/10.1007/s11165-010-9192-3
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11165-010-9192-3