An innovative cycle-based learning approach to teaching with analog sandbox models

Q1 Social Sciences

Journal of Geoscience Education Pub Date : 2022-07-13 DOI:10.1080/10899995.2022.2097566

C. J. Rowan, B. Mulvey

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引用次数: 0

Abstract

Abstract Scaled analog modeling (“sandbox modeling”) allows deformational processes, such as the development of a mountain belt, to be observed in real time in a classroom setting. However, the actual learning gains from exposure to sandbox modeling in geology courses in higher education settings have not been explicitly studied. We begin to investigate the possible effects of incorporating a sandbox modeling activity on geologic understanding in an upper-level tectonics class. The designed activity utilized a cycle-based learning approach, where the 11 participating students predicted outcomes of different deformation experiments and then evaluated and revised their predictions in the light of their experimental observations. Scored predictive sketches and a spatial visualization test administered before and after the sandbox activity demonstrate improvements in geological understanding of deformation, the influence of different mechanical properties on deformation style, and penetrative thinking skill. The observed gains were particularly marked for students who had poorly developed penetrative thinking skills prior to the activity. These results indicate that the use of sandbox models in the classroom may have a measurable effect on penetrative thinking skills and geologic understanding, particularly in students with less expertise. However, further study is required to test if these effects can be reproduced, and shown to be statistically significant, in larger groups of students.

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一种创新的基于循环的学习方法，用于模拟沙箱模型的教学

抽象缩放模拟建模（“沙盒建模”）允许在课堂环境中实时观察变形过程，如山区的发展。然而，在高等教育环境中，地质课程中接触沙箱建模的实际学习收益尚未得到明确研究。我们开始研究将沙箱建模活动纳入上层构造类别对地质理解的可能影响。设计的活动采用了基于循环的学习方法，11名参与的学生预测了不同变形实验的结果，然后根据他们的实验观察结果评估和修改了他们的预测。沙箱活动前后进行的评分预测草图和空间可视化测试表明，在地质上对变形的理解、不同力学性质对变形风格的影响以及渗透性思维技能方面有所提高。观察到的收获对于那些在活动前渗透性思维技能发展不佳的学生来说尤其显著。这些结果表明，在课堂上使用沙盒模型可能会对渗透性思维技能和地质理解产生可衡量的影响，尤其是在专业知识较少的学生中。然而，还需要进一步的研究来测试这些影响是否可以在更大的学生群体中重现，并显示出统计学意义。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Geoscience Education Social Sciences-Education

CiteScore

3.20

自引率

0.00%

发文量

期刊介绍： The Journal of Geoscience Education (JGE) is a peer-reviewed publication for geoscience education research, and serves as an international forum for research concerning the pedagogy, assessment, and philosophy of teaching and learning about the geosciences and related domains. JGE is a publication of the National Association of Geoscience Teachers, a non-profit, member-driven organization that supports a diverse, inclusive, and thriving community of educators and education researchers to improve teaching and learning about the Earth.