Asynchronous student engagement in analysis of climate data achieves learning objectives related to climate change understanding, statistical competence, and climate anxiety
Q1 Social Sciences
T. Meixner, B. Ciancarelli, E. Farrell, Silva D. García, T. Josek, M. Kelly, P. Meister, D. Soule, R. Darner
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Abstract
Learning in asynchronous online environments has gained importance over the last several decades, and educational environment shifts from the COVID-19 pandemic appear to have increased this need. Science educators and students need information about which approaches work in the asynchronous environment where informal feedback tends to be reduced, compared to other teaching modalities. In this study, we asynchronously implemented a learning module across 5 institutions that guided students (N = 199) from prescriptive data analysis through guided inquiry and eventually to open inquiry. The module focuses on the science behind climate change. Students work with the same authentic data sets used by professional scientists to examine geologic history and causes of climate change. By analyzing contemporary atmospheric carbon dioxide and temperature data and then using the 800,000-year record available from the Vostok ice core proxy record of atmospheric properties, students identify the causes of climate change and discover the unprecedented nature of recent atmospheric changes. Using a pre/post-module assessment, we demonstrate improvement in students' understanding of climate change processes and statistical methods used to analyze data. However, there was no evidence that the module develops students' scientific reasoning about the relationship between causation and correlation. Students maintained that correlation is not causation, even when a robust causal mechanism (i.e., the greenhouse effect) explains the link between atmospheric carbon dioxide and temperature. Finally, our analysis indicated that generally, anxiety about climate change was reduced during the module, such that students become less anxious about the climate change the more they learn about it. However, science-denying students experienced much higher anxiety about climate change than students who accepted the scientific consensus about climate change. Climate science-dissenting students were so few in this study that a statistical comparison was not possible, but this intriguing finding warrants further investigation of the role of anxiety in science denial. Mainly, this study demonstrates how asynchronous online learning environments can indeed support the achievement of learning objectives related to conducting authentic science, such as increasing understanding of climate change and statistical concepts, all while not provoking anxiety about climate change. © 2023 The Author(s). Published with license by Taylor & Francis Group, LLC.
异步参与气候数据分析的学生实现了与气候变化理解、统计能力和气候焦虑相关的学习目标
在过去几十年中,在异步在线环境中学习变得越来越重要,而2019冠状病毒病大流行导致的教育环境转变似乎增加了这一需求。科学教育工作者和学生需要了解哪些方法在非同步环境中有效,因为与其他教学方式相比,非正式反馈往往会减少。在本研究中,我们在5所院校异步实施了一个学习模块,引导学生(N = 199)从规定性数据分析到指导性探究,最终走向开放性探究。该模块侧重于气候变化背后的科学。学生使用与专业科学家相同的真实数据集来研究地质历史和气候变化的原因。通过分析当代大气二氧化碳和温度数据,然后利用沃斯托克冰芯大气特性代理记录的80万年记录,学生们确定了气候变化的原因,并发现了最近大气变化的前所未有的性质。通过模块前/模块后评估,我们展示了学生对气候变化过程和用于分析数据的统计方法的理解的改善。然而,没有证据表明该模块培养了学生对因果关系和相关关系的科学推理。学生们坚持认为相关性不是因果关系,即使有一个强有力的因果机制(例如,温室效应)解释了大气二氧化碳和温度之间的联系。最后,我们的分析表明,总体而言,在模块学习期间,学生对气候变化的焦虑程度有所降低,因此学生对气候变化的焦虑程度越低。然而,否认科学的学生比接受气候变化科学共识的学生对气候变化的焦虑程度要高得多。在这项研究中,反对气候科学的学生很少,因此无法进行统计比较,但这一有趣的发现值得进一步调查焦虑在否认科学中的作用。主要是,本研究展示了异步在线学习环境如何确实支持实现与进行真实科学相关的学习目标,例如增加对气候变化和统计概念的理解,同时不会引发对气候变化的焦虑。©2023作者。由Taylor & Francis Group, LLC授权出版。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
来源期刊
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.