Chemistry students’ conceptual difficulties and problem solving behavior in chemical kinetics, as a component of an introductory physical chemistry course

IF 2.2 Q2 EDUCATION, SCIENTIFIC DISCIPLINES
Charalampia Stroumpouli, Georgios Tsaparlis
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Abstract

Abstract The identification of undergraduate chemistry students’ conceptual difficulties and common mistakes with basic concepts and problems in chemical kinetics provided the aim for this study, which involved 2nd-year/4th semester students who had passed the chemical kinetics component of a physical chemistry course. The study involved the analysis, evaluation and interpretation of students’ answers to the final examination in chemical kinetics. Three achievement groups, for the various topics, were identified: Group A, high achievement (mean ≈ 85%): (a) the steps in a chain-reaction mechanism, (b) integrated 1st- and 2nd-order rate laws; and (c) the Lindemann–Hinshelwood mechanism. Group B, intermediate achievement (mean ≈ 74%): (a) half-life, (b) instantaneous rate and the extent of reaction variable (ξ), (c) the Michaelis–Menten mechanism, and (d) theoretical rate law not asking for a final formula. Group C, low achievement (mean ≈ 54%): (a) experimental rate law and the reaction rate constant on the basis of an experimental-data table, (b) extracting the theoretical rate law, and (c) the Arrhenius equation. Students’ errors and misconceptions have also been identified. Successful students tended to respond well to straightforward questions on the theory of the subject, but had difficulties when solving problems. It is essential that teachers understand the potential of their students, especially possible misconceptions they may hold, and the teaching approaches that may contribute to overcoming the student difficulties. Problems in chemical kinetics can be very demanding both in terms of algebraic manipulations and conceptually. Teaching should focus on problem solving, with the emphasis on students themselves trying to solve the problems.
化学学生在化学动力学中的概念困难和解决问题的行为,作为物理化学入门课程的组成部分
摘要本研究以通过物理化学课程化学动力学部分的二年级/四学期学生为对象,研究化学本科生对化学动力学基本概念和问题的理解困难和常见错误。这项研究包括分析、评价和解释学生化学动力学期末考试的答案。对于不同的主题,确定了三个成就组:A组,高成就(平均≈85%):(A)链式反应机制的步骤,(b)综合的一阶和二阶速率定律;(c) Lindemann-Hinshelwood机制。B组,中间成果(平均值≈74%):(a)半衰期,(B)瞬时速率和反应变量的大小(ξ), (c) Michaelis-Menten机理,(d)不要求最终公式的理论速率定律。C组成绩低(平均≈54%):(a)根据实验数据表得到实验速率定律和反应速率常数,(b)提取理论速率定律,(C)得到Arrhenius方程。学生的错误和误解也被发现。成功的学生往往能很好地回答有关该学科理论的直接问题,但在解决问题时却有困难。教师必须了解学生的潜力,特别是他们可能持有的误解,以及可能有助于克服学生困难的教学方法。化学动力学中的问题在代数操作和概念上都是非常苛刻的。教学应注重解决问题,强调学生自己努力解决问题。
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