ABSTRACT
Ever since the COVID-19 pandemic, higher education witnessed a paradigm shift in the teaching-learning strategies everywhere from the original way where everything was largely conducted face-to-face. Teachers, educators, and students had to suddenly move to the virtual mode to continue their classes in schools, institutes, and universities. Recently, many published studies have revealed the utmost need to improve teaching strategies, particularly in an online lecture setting. However, the major impediment was observed in higher educational institutions (HEIs) where teachers had to conduct laboratory experiments in hard sciences, particularly in physics, chemistry and, biochemistry. Of these subjects taught in graduate classes, chemistry is a complex subject. A chemistry learner needs to acquire hands-on experience, especially when performing organic preparations and instrumental analyses. Chemistry teachers believed that nothing could ever replace a traditional laboratory setting, but now the situation has changed to a certain extent. It has always been argued that students do not learn by merely clicking on simulated glassware and instruments. In a typical organic chemistry laboratory, students prepare organic compounds, purify them, and determine various properties of the pure compounds. Students gain experience by trial-error while adding reagents in organic preparation, devising reaction mechanisms, observing the physical properties of purified compounds, and even separating complex mixtures. Virtual laboratories cannot replace all these with a mere simulator, but when one deals with corrosive chemicals and advanced instrumental methods, it seems a plausible solution to augment them with traditional laboratories. It was found that using advanced level of online screen experiments improved students understanding and also helped them score well in their laboratory assessments. Virtual simulations cannot replace traditional laboratories since many experiments require hands-on tool abilities, smelling, seeing colored complexes, and trial-error strategies. It was also observed that experiments that require costly instruments can be carried as a remote trigger, paving the way to augment virtual experiments in the future chemistry laboratory. The chapter discusses the pedagogical design for graduate students in a virtual chemistry laboratory and live demonstrations performed in the traditional laboratory. In this chapter chemistry experiments based on organic synthesis, stereochemistry and spectroscopy on a virtual screen have been studied. The different modalities of conducting virtual screen experiments, assessment strategies, and government initiatives are also highlighted. This chapter concludes with current and future trends of virtual chemistry laboratories with highlights on the barriers, opportunities, and key measures to resolve them.
