原子力显微镜在聚合物晶体和聚合物共混物教学中的应用

IF 2.5 3区 教育学 Q2 CHEMISTRY, MULTIDISCIPLINARY
Maksim Dolmat*, Veronika Kozlovskaya and Eugenia Kharlampieva*, 
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引用次数: 0

摘要

扩大本科课程的重要组成部分是纳入纳米科学和纳米材料的实验室实验,这些实验通过在食品、化妆品、农业和医学中的使用对健康和环境产生重大影响。我们设计了一个基于原子力显微镜(AFM)分析聚合物共混物和晶体物理特性的实验室实验,包括表面形态、杨氏模量、变形和刚度。实验室练习让学生了解聚乙二醇结晶和不混溶聚苯乙烯/聚丁二烯混合物形成的主要方面,然后是光学显微镜和AFM表征。除了通过AFM形貌扫描提供有关样品表面形态和微观结构的信息外,纳米压痕测量还允许以纳米级分辨率对材料进行机械表征。机械表征为学生提供了一个更广泛的应用领域,他们可以利用自己的化学理解来调节材料的物理特性。AFM力曲线图能够评估复合材料中成分的分布,同时以纳米级精度独立分析每种成分。AFM的多功能性大大增加了可以在纳米科学和纳米材料本科课程中开发的实验室实验的数量。获得的关于聚合物共混、结晶及其纳米级表征的知识为学生提供了实用和可转移的技能,他们可以在其他化学和工程课程中应用这些技能来解决现实世界中的问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Atomic Force Microscopy for Teaching Polymer Crystals and Polymer Blends

Atomic Force Microscopy for Teaching Polymer Crystals and Polymer Blends

The essential component of expanding an undergraduate curriculum is the inclusion of lab experiments in nanoscience and nanomaterials, which significantly impact health and the environment through their use in food, cosmetics, agriculture, and medicine. We designed a laboratory experiment based on the atomic force microscopy (AFM) analysis of the physical characteristics of polymer blends and crystals, including surface morphology, Young’s modulus, deformation, and stiffness. The laboratory exercise exposes students to the main aspects of the crystallization of polyethylene glycol and the formation of an immiscible polystyrene/polybutadiene blend, followed by optical microscopy and AFM characterization. In addition to providing information about the surface morphology and microstructure of the samples through AFM topography scanning, nanoindentation measurements allow for the mechanical characterization of materials with nanoscale resolution. Mechanical characterization offers students a broader application area where they can use their chemical understanding to regulate the material’s physical characteristics. AFM force curve mapping enables assessment of the components’ distribution in composite materials while analyzing each constituent independently with nanoscale precision. The versatility of AFM considerably increases the number of laboratory experiments that can be developed in undergraduate courses on nanoscience and nanomaterials. The knowledge acquired about polymer blending, crystallization, and their characterization at the nanoscale equips students with practical and transferable skills that they may apply in other chemistry and engineering classes to address real-world issues.

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来源期刊
Journal of Chemical Education
Journal of Chemical Education 化学-化学综合
CiteScore
5.60
自引率
50.00%
发文量
465
审稿时长
6.5 months
期刊介绍: The Journal of Chemical Education is the official journal of the Division of Chemical Education of the American Chemical Society, co-published with the American Chemical Society Publications Division. Launched in 1924, the Journal of Chemical Education is the world’s premier chemical education journal. The Journal publishes peer-reviewed articles and related information as a resource to those in the field of chemical education and to those institutions that serve them. JCE typically addresses chemical content, activities, laboratory experiments, instructional methods, and pedagogies. The Journal serves as a means of communication among people across the world who are interested in the teaching and learning of chemistry. This includes instructors of chemistry from middle school through graduate school, professional staff who support these teaching activities, as well as some scientists in commerce, industry, and government.
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