New Directions in the Teaching of Natural Sciences

Practical work is an integral part of teaching and learning in STEM. It can help to deliver many learning outcomes - manipulative skills, observation and description, motivation, creative thinking, problem-solving abilities, and critical attitudes, as well as conceptual understanding. In recent years the already weak provision of the STEM practical curriculum in Sub Saharan Africa SSA has been undermined further by pandemic constraints. Online practical work is expanding rapidly in both scale and sophistication worldwide and it offers a credible means of mitigating such problems and improving access in SSA.

This study examines issues and prospects for online practical work in SSA. It includes a brief summary of the present position and presents the views of stakeholders gathered using semi structured interviews. These focused on their attitudes towards introducing new learning technologies and related approaches in the teaching and learning of practical work in science.

The results showed that many of the educators interviewed are enthusiastic about the opportunities afforded by online practical work and see such innovation as a useful response to the pandemic. They also assert their readiness to embrace new technologies in STEM practical work but warn of the challenges, notably access to resources and the lack of the teaching skills required to engage learners in effective online practical work. The students have been disappointed by online versions of conventional face to face teaching and many are sceptical about online practical work. Resource and cost issues dominate their thinking. Science educators will require extensive training if online learning technologies are to be harnessed successfully to provide practical science activities in SSA.

Abrahams, I. & Millar, R. (2008). Does practical work really work? A study of the effectiveness of practical work as a teaching and learning method in school science, International Journal of Science Education, 30(14): 1945-69.

Babalola, F. E. (2017). Advancing Practical Physics in Africa’s Schools (Doctoral dissertation). The Open University, Milton Keynes, England.

Babalola, F. E., Lambourne, R. J. & Swithenby, S. J. (2020). The Real Aims that Shape the Teaching of Practical Physics in Sub-Saharan Africa. International Journal of Science and Mathematics Education, 18, 259-278

Bhukuvhani, C., Mupa, M., Mhishi, M. & Dziva, D. (2012). Science practical work instructional technologies and open distance learning in science teacher training: A case study in Zimbabwe. International Journal of Education and Development using Information and Communication Technology 8(2), 17-27

Darrah, M., Humbert, R., Finstein, J., Simon., M. & Hopkins, J. (2014). Are Virtual Labs as Effective as Hands-on Labs for Undergraduate Physics? A Comparative Study at Two Major Universities. Journal of Science Education and Technology. 23, 803-814

Eickelmann, B. & Vennemann, M. (2017) Teachers‘attitudes and beliefs regarding ICT in teaching and learning in European countries. European Educational Research Journal. 16(6) : 733-761

Hogarth S., Bennett, J., Lubben, F., Campbell, B. & Robinson, A. (2020).ICT in Science Teaching: The Effect of ICT Teaching Activities in Science Lessons on Students’ Understanding of Science Ideas. Technical Report. London: EPPI-Centre, Social Science Research Unit, Institute of Education, University of London. Available from http://eppi.ioe.ac.uk/reel/. Accessed: 16th November 2021.

Kirschner, P. & Huisman, W. (1998). “Dry laboratories in science education: Computer-based practical work. International Journal of Science Education 20, 665-682

Lunetta, V. N., Hofstein, A. & Clough, M.P., (2007). Teaching and learning in the school science laboratory. An analysis of research, theory, and practice. In S.K Abell and N.G. Lederman (Eds.), Handbook of Research on science Education. Malawi, N.J: Lawrence Erlbaum Associates, pp. 393-431.

Millar, R. (2006). Twenty First Century Science: Insights from the design and implementation of a scientific literacy approach in school science. International Journal of Science Education, 28(13), 1499-1521

Millar, R., Le Marechal, J. F., & Tiberghien, A. (1999). ‘Mapping’ the domain: varieties of practical work. In J. Leach & A. C. Paulsen (Eds.), Practical work in science education: recent research studies (pp. 33-59), Denmark, Roskilde: University Press.

Ofcom Report. (2017). The International Communications Market – Telecoms and Networks. Available from https://www.ofcom.org.uk/__data/assets/pdf_file/0026/108908/icmr-2017-telecoms-networks.pdf (page 48), (Accessed 9/12/21)

Rodriguesa, H., Almeida, F., Figueiredo, V., Lopes, S. L. (2019). Tracking e-learning through published papers: A systematic review. Computer Education 136, 87-98

SCORE (2009a). Getting practical: a framework for practical science in schools. London: DSCF. Available fromwww.score-education.org/downloads/practical_work/framework.pdf Accessed: 13th October 2021

SCORE (2009b). Practical Work in Science: a report and proposal for a strategic framework. Gatsby technical education projects. Available from http://www.score-education.org/media/3668report.pdf Accessed: 11th November 2021

Triona, L. & Klahr, D. (2003). “Point and click or grab and heft: comparing the influence of physical and virtual instructional materials on elementary school students’ ability to design experiments” Cognitive Instruction 21, 149-173

Webb, M. (2010). Technology-mediated learning In J. Dillon & J. Osborne (Eds.), Good practice in science teaching: what research has to say (2nd Ed.), London: McGraw-Hill.

World Bank Databank (2019). Access to Electricity. Available from https://data.worldbank.org/indicator/EG.ELC.ACCS.ZS. (Accessed 9/12/21)

Zacharia, Z. C. (2007). Comparing and combining real and virtual experimentation: an effort to enhance students’ conceptual understanding of electric circuits, Journal of Computer Assisted Learning, 23(2): 120-32.

Zhai, G., Wang, Y. & Liu, L. (2012). Design of Electrical Online Laboratory and E-learning. In Proceedings of the 2012 International Conference on Future Computer Supported Education, Seoul, Korea 22-23 August 2012. pp 325-330