Surface effects and symmetry lowering effect on the anisotropic bending and equilibrium of freestanding nanofilms

IF 1.9 4区工程技术 Q3 MECHANICS

Mechanics Research Communications Pub Date : 2023-10-11 DOI:10.1016/j.mechrescom.2023.104199

Jiangang Li , Yuning Du , Huihui Xu , Zhixiang Gao , Hua Wang

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引用次数: 0

Abstract

A self-consistent theory for describing self bending, self equilibrium and symmetry lowering of nanofilms was proposed in this paper. The lowered symmetry and corresponding additional elastic parameter were considered to describe the mechanical properties of nanofilms. A freestanding nanofilm may spontaneously roll into a nanotube due to intrinsic surface stress imbalance. It is not necessarily isotropic for surface stress. The anisotropic surface stress is possible, Si nanofilm with (001) surface may behave (2 × 1) reconstruction, for example. The anisotropic surface stress induces anisotropic bending. And then, the isotropic Stoney formular should be modified to suit the anisotropic surface stress effect. A theory for anisotropic bending should be established. On the other hand, intrinsic surface stress balance induces uniform in-plane deformation of nanofilms. The theory in this paper was used to predict equilibrium strains of Cu, Ni, Ag, Au, Pd and Pt nanofilms, and was used to research Si nanofilm rolling behavior.

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表面效应和对称性降低对独立纳米膜各向异性弯曲和平衡的影响

本文提出了描述纳米薄膜自弯曲、自平衡和对称性降低的自洽理论。考虑了降低的对称性和相应的附加弹性参数来描述纳米膜的力学性能。由于固有的表面应力不平衡，独立的纳米膜可能自发地卷成纳米管。表面应力不一定是各向同性的。各向异性的表面应力是可能的，例如，具有（001）表面的Si纳米膜可以进行（2×1）重建。各向异性表面应力引起各向异性弯曲。然后，对各向同性Stoney公式进行修正，以适应各向异性表面应力效应。应该建立各向异性弯曲的理论。另一方面，固有的表面应力平衡导致纳米膜的均匀平面内变形。本文的理论用于预测Cu、Ni、Ag、Au、Pd和Pt纳米膜的平衡应变，并用于研究Si纳米膜的轧制行为。

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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来源期刊

Mechanics Research Communications 物理-力学

CiteScore

4.10

自引率

4.20%

发文量

114

审稿时长

9 months

期刊介绍： Mechanics Research Communications publishes, as rapidly as possible, peer-reviewed manuscripts of high standards but restricted length. It aims to provide: • a fast means of communication • an exchange of ideas among workers in mechanics • an effective method of bringing new results quickly to the public • an informal vehicle for the discussion • of ideas that may still be in the formative stages The field of Mechanics will be understood to encompass the behavior of continua, fluids, solids, particles and their mixtures. Submissions must contain a strong, novel contribution to the field of mechanics, and ideally should be focused on current issues in the field involving theoretical, experimental and/or applied research, preferably within the broad expertise encompassed by the Board of Associate Editors. Deviations from these areas should be discussed in advance with the Editor-in-Chief.