Proposal Title
Enhancing geological skills through tactile learning with interactive multi-layered three-dimensional printed geological models of southern Ontario.
Session Type
Presentation
Room
Somerville House, room 3345
Start Date
13-7-2023 11:00 AM
End Date
13-7-2023 11:20 AM
Keywords
Tactile learning, geology, 3D print model, southern Ontario
Primary Threads
Education Technologies and Innovative Resources
Abstract
In the digital age we often forget about the immense value of tactile learning. In other words, learning by touching and moving (i.e., assembling and disassembling) physical objects. Here we introduce the newly developed three dimensional (3D) printed models created by the Oil, Gas, Salt Resource Library that provide an unprecedented regional 3D perspective of the subsurface geology of southern Ontario. These innovative models simplify data from thousands of borehole records that are part of a 3D digital model focusing on the Paleozoic bedrock in southern Ontario (Carter et al. 2021). The 4-layer multi-coloured 3D print models are highly simplified versions of the 52-layer digital models. Nevertheless, the physical model encapsulates numerous aspects of the basin stratigraphy, geometry, and topography. Piloting the use of 3D printed geological models in undergraduate university courses (future Geoscientists and Geologic Engineers) in the form of laboratory exercises has shown to successfully bridge learning gaps in regard to conceptualizing spatial features (i.e., lateral extent, vertical thickness, and aspect of geologic layers), temporal context (i.e., relative age and preserved or missing layers) and economic resource formations (i.e., salt, water, oil, gas). The 3D print models also help students connect field observations with geologic interpretations (i.e., surficial mapping, subsurface borehole data to 3D surfaces, geometric shapes) as well as relating subsurface geology to surface features (i.e., landforms like escarpments and location of resources). In this workshop we will demonstrate the use of 3D printed models needed to bridge vital gaps in knowledge between real digital data and everyday life, applicable to the Geosciences. And then ask for help reflecting upon the use and impact of 3D printed models in other disciplines. Please bring your own device (smartphone, laptop, tablet) so you can experiment with resources and explore potential avenues to improve teaching and learning.
Elements of Engagement
- We plan on bringing 10 traditional 2D paper (Quaternary and Bedrock) maps, 10 new relatively small-scale 3D print models, and 10 new relatively medium-scale 3D printed models.
- Workshop participants will be able to examine, measure, assemble and disassemble 3D printed geological models and explore the value of simplified 3D models extending beyond traditional maps and into the realm of 3D digital models.
- We plan on interactively exploring the vital role of tactile learning in the Geosciences and then reflecting on the use and impact of tactile learning in other disciplines.
Creative Commons License
This work is licensed under a Creative Commons Attribution-Noncommercial-No Derivative Works 4.0 License.
Enhancing geological skills through tactile learning with interactive multi-layered three-dimensional printed geological models of southern Ontario.
Somerville House, room 3345
In the digital age we often forget about the immense value of tactile learning. In other words, learning by touching and moving (i.e., assembling and disassembling) physical objects. Here we introduce the newly developed three dimensional (3D) printed models created by the Oil, Gas, Salt Resource Library that provide an unprecedented regional 3D perspective of the subsurface geology of southern Ontario. These innovative models simplify data from thousands of borehole records that are part of a 3D digital model focusing on the Paleozoic bedrock in southern Ontario (Carter et al. 2021). The 4-layer multi-coloured 3D print models are highly simplified versions of the 52-layer digital models. Nevertheless, the physical model encapsulates numerous aspects of the basin stratigraphy, geometry, and topography. Piloting the use of 3D printed geological models in undergraduate university courses (future Geoscientists and Geologic Engineers) in the form of laboratory exercises has shown to successfully bridge learning gaps in regard to conceptualizing spatial features (i.e., lateral extent, vertical thickness, and aspect of geologic layers), temporal context (i.e., relative age and preserved or missing layers) and economic resource formations (i.e., salt, water, oil, gas). The 3D print models also help students connect field observations with geologic interpretations (i.e., surficial mapping, subsurface borehole data to 3D surfaces, geometric shapes) as well as relating subsurface geology to surface features (i.e., landforms like escarpments and location of resources). In this workshop we will demonstrate the use of 3D printed models needed to bridge vital gaps in knowledge between real digital data and everyday life, applicable to the Geosciences. And then ask for help reflecting upon the use and impact of 3D printed models in other disciplines. Please bring your own device (smartphone, laptop, tablet) so you can experiment with resources and explore potential avenues to improve teaching and learning.