Using electrostatic potential maps as visual representations to promote better understanding of chemical bonding

IF 2.2 Q2 EDUCATION, SCIENTIFIC DISCIPLINES
Georgios Tsaparlis, Giannoula Pantazi, E. Pappa, B. Byers
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引用次数: 4

Abstract

Abstract Static visual representations (VRs) of chemical structures are necessary for an understanding of chemical bonding, a topic which continues to lead to learning difficulties and misconceptions for many students. The efficacy and problems associated with the use of VRs of chemical structures and chemical bonding in the form of electrostatic potential maps resulting from accurate quantum mechanical calculations are the subject of this study, which involved a sample of first year, second semester students, studying the elective course “Science Education” (N = 31). Students distinguished between nonpolar and polar covalent bonding, however, they encountered difficulties with concepts related to ionic bonding. Most students did not employ multistructural thinking (in the sense of the SOLO taxonomy), when providing explanations about the variation of bond polarity. Persistence of a covalent-ionic bond dichotomy was apparent, while for some, ions can be involved in both ionic and covalent bonding. Many students preferred to use their established high school knowledge. On a positive note, many students were clearly affected by the information provided by the colored VRs. Finally, the minimal experience of our students with these VRs leads us to believe that a more systematic and extensive coverage would be likely to produce improved outcomes.
使用静电势图作为视觉表示,以促进更好地理解化学键
化学结构的静态视觉表示(vr)对于理解化学键是必要的,这一主题一直导致许多学生的学习困难和误解。通过精确的量子力学计算,以静电势图的形式使用化学结构和化学键的vr的功效和问题是本研究的主题,该研究涉及一年级,第二学期的学生样本,学习选修课程“科学教育”(N = 31)。学生区分了非极性共价键和极性共价键,然而,他们在离子键相关的概念上遇到了困难。在解释键极性的变化时,大多数学生没有使用多结构思维(在SOLO分类法的意义上)。共价键和离子键的二分法是显而易见的,而对一些离子来说,离子和共价键都可以参与。许多学生更喜欢运用他们已经掌握的高中知识。积极的一面是,许多学生明显受到了有色vr提供的信息的影响。最后,我们的学生对这些虚拟现实的最少体验使我们相信,更系统和更广泛的覆盖可能会产生更好的结果。
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CiteScore
3.10
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0.00%
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