AFM Indentation on Highly Heterogeneous Materials Using Different Indenter Geometries

IF 12.2 1区 工程技术 Q1 MECHANICS
S. Kontomaris, A. Stylianou, G. Chliveros, A. Malamou
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引用次数: 3

Abstract

Hertzian mechanics is the most frequently used theory for data processing in Atomic Force Microscopy (AFM) indentation experiments on soft biological samples, due to its simplicity and significant scientific results previously published. For instance, using the Hertz model, it has been proven that there are significant differences in the mechanical properties of normal and cancerous tissues and that cancer cells’ invasive properties are correlated with their nanomechanical properties. However, many scientists are skeptical regarding the applicability of the Hertz theory to biological materials, as they are highly heterogeneous. The main critical question to be addressed is “what do we calculate” when fitting the force-indentation data to Hertz equations. Previous studies have shown that when using cylindrical, parabolic, or conical indenters, the fitting parameter is the average Young’s modulus. In this paper, it is demonstrated that it is also valid to fit equations derived from Hertzian mechanics to force-indentation data when testing soft, heterogeneous samples for any indenter geometry. The fitting factor calculated through this approach always represents the average Young’s modulus for a specific indentation depth. Therefore, Hertzian mechanics can be extended to soft heterogeneous materials, regardless of the indenter’s shape.
使用不同压头几何形状的高度非均匀材料的AFM压痕
赫兹力学是软生物样品原子力显微镜(AFM)压痕实验中最常用的数据处理理论,由于它的简单性和先前发表的重要科学结果。例如,利用赫兹模型,已经证明了正常组织和癌组织的力学特性存在显著差异,癌细胞的侵袭特性与其纳米力学特性相关。然而,许多科学家对赫兹理论在生物材料中的适用性持怀疑态度,因为它们是高度异质的。当将力压痕数据拟合到赫兹方程时,要解决的主要关键问题是“我们计算什么”。先前的研究表明,当使用圆柱形、抛物线形或锥形压头时,拟合参数为平均杨氏模量。在本文中,证明了在测试软的、非均匀的压头几何形状的样品时,用赫兹力学推导的方程拟合力压痕数据也是有效的。通过这种方法计算的拟合因子总是代表特定压痕深度的平均杨氏模量。因此,赫兹力学可以扩展到柔软的非均质材料,而不考虑压头的形状。
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来源期刊
CiteScore
28.20
自引率
0.70%
发文量
13
审稿时长
>12 weeks
期刊介绍: Applied Mechanics Reviews (AMR) is an international review journal that serves as a premier venue for dissemination of material across all subdisciplines of applied mechanics and engineering science, including fluid and solid mechanics, heat transfer, dynamics and vibration, and applications.AMR provides an archival repository for state-of-the-art and retrospective survey articles and reviews of research areas and curricular developments. The journal invites commentary on research and education policy in different countries. The journal also invites original tutorial and educational material in applied mechanics targeting non-specialist audiences, including undergraduate and K-12 students.
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