Supporting first-year students in learning molecular orbital theory through a digital learning unit

IF 2.2 Q2 EDUCATION, SCIENTIFIC DISCIPLINES Chemistry Teacher International : best practices in chemistry education Pub Date : 2023-08-17 DOI:10.1515/cti-2022-0040
David Johannes Hauck, Andreas Steffen, I. Melle
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Abstract

Abstract A large number of chemistry students drop out of their studies, often because of high requirements for content knowledge. Quantum chemical models of atomic bonding such as molecular orbital (MO) theory are particularly challenging. We aimed to develop an intervention on MO theory based on the Computer-Supported Collaborative Learning framework. First, students work independently with interactive learning videos. Then, they create concept maps about core concepts of MO theory. In this paper, we present the evaluation of this intervention in terms of content knowledge, considering person-specific characteristics. Additionally, we compare three different treatment groups with varying materials and group arrangements, and prospective chemistry teachers with other first-year students. Our results show that students can answer single-choice questions well with the prior knowledge from their first-year chemistry course. Answering open-ended questions is more difficult. Nevertheless, they can improve significantly in both categories by working with the learning videos; creating concept maps does not lead to significant content knowledge changes. There are also no significant differences between the three treatment groups, or between teacher students and other chemistry freshmen. Regarding prior knowledge, differences depending on gender and school-leaving grades can be measured, whereas the choice of courses in school has no effect.
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支持一年级学生通过数字学习单元学习分子轨道理论
摘要大量化学专业的学生辍学,往往是因为对内容知识的要求很高。原子键合的量子化学模型,如分子轨道理论,特别具有挑战性。我们的目标是开发一个基于计算机支持的协作学习框架的MO理论干预。首先,学生通过互动学习视频独立学习。然后,他们创建了MO理论核心概念的概念图。在本文中,我们从内容知识的角度,考虑到个人的具体特征,对这种干预进行了评估。此外,我们比较了三个不同的治疗组,不同的材料和组安排,以及未来的化学老师和其他一年级学生。我们的研究结果表明,学生能够很好地利用一年级化学课程的先验知识回答单选题。回答开放式问题比较困难。尽管如此,通过使用学习视频,他们可以在这两个类别中都有显著的改进;创建概念图不会导致内容知识的显著变化。三个处理组之间,或师范生与其他化学新生之间也没有显著差异。关于先验知识,可以衡量不同性别和离校成绩的差异,而学校课程的选择没有影响。
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