Abstract
3D printing developed as a prototyping method in the early 1980s, yet it is considered as a 21st century technology for transforming digital models into tangible objects. 3D printing has recently become a critical tool in the geoscience research, education, and technical communication due to the expansion of the market for 3D printers and materials. 3D printing changes the perception of how we interact with our data and how we explain our science to non-experts, researchers, educators, and stakeholders. Hence, a one-day short course was designed and delivered to a group of professors, students, postdoctoral fellows, and technical staff to present the application of 3D printing in teaching and communication concepts in the geoscience. This case study was aimed at evaluating how a diverse group of participants with geoscience and engineering background and no prior experience with computer-aided modeling (CAD) or 3D printing could understand the principles of different 3D printing techniques and apply these methods in their respective disciplines. In addition, the course evaluation questionnaire allowed us to assess human perception of tangible and digital models and to demonstrate the effectiveness of 3D printing in data communication. The course involved five modules: 1) an introduction lecture on the 3D printing methods and materials; 2) an individual CAD modeling exercise; 3) a tour to 3D printing facilities with hands-on experience on model processing; 4) a tour to experimentation facilities where 3D-printed models were tested; and 5) group activities based on the examples of how to apply 3D printing in the current or future geoscience research and teaching. The participants had a unique opportunity to create a digital design at the beginning of the course using CAD software, analyze it and 3D print the final model at the end of the course. While this course helped the students understand how rendering algorithms could be used as a learning aid, educators gained experience in rapid preparation of visual aids for teaching, and researchers gained skills on the integration of the digital datasets with 3D-printed models to support societal and technical objectives.
Highlights
Elrod (2016) emphasized that if 3D printing would be used in the K-12 environment, students could be better prepared for careers in emerging fields of technology [e.g., science, technology, engineering, and mathematics (STEM disciplines)]
The course learning outcomes were: 1) to understand capabilities and limitations of different 3D printing techniques; 2) to demonstrate how to digitally design 3Dprintable models using CAD software, web platforms, and computed tomography data; 3) to provide the assessment of digital models and their relative replicas 3D-printed from real data; and 4) to characterize how 3D printing can increase the effectiveness of teaching and data communication
The short course presented in this study was useful for a diverse group of participants including professors, students, postdoctoral fellows, and technicians from the geoscience and engineering disciplines, because it allowed them to communicate geological concepts using digital models and their tangible counterparts. Participants demonstrated that this technology allowed them having the capacity for modification and sharing digital data and supporting educators who wanted to produce teaching models without prior expertise and in a rapid manner. While this one-day short course had five modules, participants acknowledged that the time spent on each module was adequate as the modules contained the right amount of instructions and activities
Summary
Application of 3D printing in high-school education has already shown enhanced haptic perception of the learning material. Elrod (2016) emphasized that if 3D printing would be used in the K-12 environment, students could be better prepared for careers in emerging fields of technology [e.g., science, technology, engineering, and mathematics (STEM disciplines)]. Schelly et al (2015) demonstrated that even a 3day short course for middle- and high-school teachers from a variety of disciplines (sciences, engineering, and arts) gained a high interest in utilizing this technology in their classrooms. Chien and Chu (2018) proposed that 3D printing could enable high-school students to improve their ability to transform from STEM to STEAM (science, technology, engineering, arts, and mathematics) using 3D printers and to create a bridging curriculum with respect to high-school and college students
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