An exploration of the proton NMR problem-solving approaches of undergraduate students

IF 2.2 Q2 EDUCATION, SCIENTIFIC DISCIPLINES
Sujani Gamage, Suazette Mooring
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引用次数: 0

Abstract

Abstract Problem-solving is an important component of chemistry teaching and learning. It often requires both conceptual knowledge and problem-solving skills. This study aims to examine how students solve tasks related to proton 1 H NMR spectroscopy. This study included 24 voluntary participants enrolled in second-semester organic chemistry labs in two different instructional settings (online or in person). The data were collected through interviews conducted via Webex video conferencing software and used a think-aloud protocol. The data were analyzed using an inductive coding approach to identify students’ problem-solving approaches and resources they used when solving a given 1 H NMR task that involved matching protons in a compound to specific peaks in the spectrum. The resources framework was used to capture students’ conceptual resources and problem-solving approaches. Results revealed that participants used more productive approaches than unproductive approaches while solving the problem; however, most students relied on one basic NMR concept to draw conclusions about the identity of a given peak. Also, when we observed the problem-solving resources that students utilized based on how they received NMR instruction (online or in-person), we did not observe major differences between the problem-solving resources that students used.
本科生质子核磁共振解题方法探讨
问题解决是化学教与学的重要组成部分。它通常需要概念性知识和解决问题的能力。本研究旨在考察学生如何解决与质子氢核磁共振波谱有关的任务。这项研究包括24名自愿参加第二学期有机化学实验室的志愿者,他们在两种不同的教学环境下(在线或面对面)学习。数据是通过Webex视频会议软件进行的访谈收集的,并使用了有声思考协议。使用归纳编码方法对数据进行分析,以确定学生在解决给定的1 H NMR任务时使用的解决问题的方法和资源,该任务涉及将化合物中的质子与光谱中的特定峰相匹配。资源框架用于捕获学生的概念资源和解决问题的方法。结果显示,在解决问题时,参与者使用了比非生产性方法更多的生产性方法;然而,大多数学生依靠一个基本的核磁共振概念来得出关于给定峰的身份的结论。此外,当我们观察学生根据他们接受核磁共振指导的方式(在线或面对面)使用的问题解决资源时,我们没有观察到学生使用的问题解决资源之间的主要差异。
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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CiteScore
3.10
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0.00%
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