Step away from the CAD station: A hands-on and immersive approach to second year teaching of Mechanical Engineering design

The purpose of this paper is to present a new methodology to enhance creativity within the context of learning and teaching in an engineering design module in the College of Engineering at Swansea University. The challenges to introducing creativity into an engineering undergraduate course are explored, with the main intervention—Virtual Reality for concept development—investigated through pre- and post-intervention surveys, student interviews and a focus group. Additional interventions to enhance creativity are discussed and future improvements to module design put forward

Organic Chemistry in Virtual Reality: Bridging Gaps between Two-Dimensional and Three-Dimensional Representations

The traditional two-dimensional representations in organic chemistry education highlighted the lack of depth and interactivity, impeding student learning, engagement, and comprehension. By emphasizing on the limitations of conventional educational materials, the research advocated for integrating Augmented Reality (AR) and Virtual Reality (VR) technologies, which enhance organic chemistry visualization. The main objective was to bridge the gap between two and three-dimensional perspectives, offering a more dynamic and interactive learning experience. The thesis aimed to assess traditional teaching methods in organic chemistry—lectures, textbooks, and laboratory exercises. It also aimed to identify their challenges in conveying complex molecular structures and reactions effectively. Additionally, it explored the integration of Virtual Reality (VR) and Augmented Reality (AR) with these conventional methods. The goal had been to develop a cohesive educational framework that combined the strengths of both traditional and modern technological approaches. This blended learning model was meant to improve student engagement and understanding by incorporating dynamic visualizations into lectures as well as interactive content into textbooks. Building on this premise, the research focused on the following questions: 1. What challenges do traditional teaching methods face in teaching organic chemistry concepts adequately? 2. What advantages do VR and AR offer in organic chemistry education compared to traditional methods? 3. What impact do VR and AR technologies have on student engagement in organic chemistry compared to traditional teaching methods? 4. How can VR and AR be tailored to meet pedagogical and andragogical needs in organic chemistry education? 5. Why are VR and AR more effective than traditional methods in enhancing learning in organic chemistry? 6. What are the best strategies for integrating VR and AR into the organic chemistry curricula to enhance learning alongside traditional methods? 7. How can AR and VR in organic chemistry education be aligned with Vygotsky’s Zone of Proximal Development to improve learning outcomes? 8. How can AR and VR be personalized in organic chemistry education to support individual learning and Piaget\u27s theory of self-learning? 9. What are the benefits and challenges of applying the \u27Ship Early, Ship Often\u27 approach to developing AR and VR tools in organic chemistry education? Upon the completion of this research, a literature review was conducted additionally as well as visual and content analyses. Based upon the research conducted, a visual solution was created to guide curriculum developers, textbook publishers, researchers, and educators in integrating VR and AR technologies into traditional organic chemistry curricula. The deliverable theory of the visual was a high-fidelity wireframe prototype created for VR and AR in Organic Chemistry, designed to enhance student engagement and understanding by combining immersive technology with traditional teaching methods. The project also featured a responsive website to inform stakeholders about the benefits of this integration, supported by print media like brochures, posters, and billboards for broader outreach and awareness. The high-fidelity wireframe prototype with the responsive website and supporting print media, were crucial elements in reshaping organic chemistry education, bridging the gap between traditional pedagogy and andragogy as well as futuristic learning paradigms

Analisis bibliometrik: trend penelitian tentang kemampuan spasial dalam pembelajaran matematika (1994-2023)

The aim of this study was to review the landscape of leading research related to spatial skills in mathematics education from 1994 to 2023. Data were taken from the Scopus database as many as 466 and filtered to 116. The data obtained was then analyzed using bibliometric analysis with science mapping and performance techniques. Based on the results of bibliometric analysis, it can be seen that the year 2021 and 2022 has the most published articles, which are respectively 8 article. Reference tendencies related to spatial skills in mathematics education, exist 406 excellent reference in 2010. United states that it is the country that has published the most articles related to spatial abilities in mathematics learning with 49 publications and 28 links of cooperation with other countries. The focus of spatial skills research in mathematics learning leads to 1) Visualization; 2) virtual reality; 3) Mental rotation

Technology Enhanced Learning Guide

Technology is changing how students learn and how we research. Perhaps you want to use technology to enhance communication or improve student support. You may want create a distance learning activity, a flexibly delivered module or indeed a whole course. You may simply want to find out where to find authoritative information, or to see what support exists for this type of work. The University is committed to delivering high quality learning and teaching, using technology where appropriate, in order to offer a distinctive Southampton educational experience. Technology Enhanced Learning (TEL), also known as e‑learning, is becoming increasingly important to students, teaching staff and the institution. This guide highlights some of the most important matters to consider. It is intended to help you to tackle the key issues that determine the success of TEL projects and to work on those projects in a considered way. Written with the input of colleagues from around the University, it prompts you to ask important questions and points you to sources of up-to-date knowledge and advice. Technology changes rapidly. This guide is about managing the work in a practical way. The University supports the use of a variety of TEL approaches for teaching and learning and colleagues are ready to offer their experience and advice. Each person has distinctive skills and specific experiences. No single person will have all the answers you are looking for. Be ready to investigate alternative approaches that suit you and your students’ needs in different ways. - Madeline Paterson, University of Southampto