Hook's law scaled broken-bond model for surface energy: From metals to ceramics

Ying Zhang; William Yi Wang; Peixuan Li; Ke Ren; Yixuan He; Xingyu Gao; Hongchao Kou; Jun Wang; Yiguang Wang; Haifeng Song; Xiubing Liang; Jinshan Li

doi:10.1016/j.scriptamat.2024.116026

Hook's law scaled broken-bond model for surface energy: From metals to ceramics

Ying Zhang, William Yi Wang^*, Peixuan Li, Ke Ren, Yixuan He, Xingyu Gao, Hongchao Kou, Jun Wang, Yiguang Wang, Haifeng Song, Xiubing Liang, Jinshan Li

^*Corresponding author for this work

Institute of Advanced Structure Technology

Research output: Contribution to journal › Article › peer-review

2 Citations (Scopus)

Abstract

Innovative surfaces via lattice engineering are crucial challenges and critical to enhance the mechanical and functional properties of advanced materials. Here, a universal linear scaling rule in terms of key property parameters (KPPs) is proposed to estimate the modifications of local lattice strain (LLS) caused by the surface, in which the bulk modulus (B), the B/G ratio, and the bond energy are utilized to describe the KPPs of the BCC and FCC, the isotropic HCP, and the polarized A₂B₂O₇-type Pyrochlore, individually. The modified broken-bond model by the Hook's law is addressed to predict the elastic-energy-corrected surface energy efficiently and precisely, which is capable to deal with the complex of geometry, chemistry, charge states of clean surface and are verified and validated in 28 metals and ceramics. While the LLS of metals is caused by the improved bond length, the ceramics one is yielded by the reduced one of polarized surface.

Original language	English
Article number	116026
Journal	Scripta Materialia
Volume	244
DOIs	https://doi.org/10.1016/j.scriptamat.2024.116026
Publication status	Published - 15 Apr 2024

Keywords

Broken-bond model
Elastic energy
Lattice engineering
Surface energy

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10.1016/j.scriptamat.2024.116026

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title = "Hook's law scaled broken-bond model for surface energy: From metals to ceramics",

abstract = "Innovative surfaces via lattice engineering are crucial challenges and critical to enhance the mechanical and functional properties of advanced materials. Here, a universal linear scaling rule in terms of key property parameters (KPPs) is proposed to estimate the modifications of local lattice strain (LLS) caused by the surface, in which the bulk modulus (B), the B/G ratio, and the bond energy are utilized to describe the KPPs of the BCC and FCC, the isotropic HCP, and the polarized A2B2O7-type Pyrochlore, individually. The modified broken-bond model by the Hook's law is addressed to predict the elastic-energy-corrected surface energy efficiently and precisely, which is capable to deal with the complex of geometry, chemistry, charge states of clean surface and are verified and validated in 28 metals and ceramics. While the LLS of metals is caused by the improved bond length, the ceramics one is yielded by the reduced one of polarized surface.",

keywords = "Broken-bond model, Elastic energy, Lattice engineering, Surface energy",

author = "Ying Zhang and Wang, {William Yi} and Peixuan Li and Ke Ren and Yixuan He and Xingyu Gao and Hongchao Kou and Jun Wang and Yiguang Wang and Haifeng Song and Xiubing Liang and Jinshan Li",

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year = "2024",

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doi = "10.1016/j.scriptamat.2024.116026",

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T1 - Hook's law scaled broken-bond model for surface energy

T2 - From metals to ceramics

AU - Zhang, Ying

AU - Wang, William Yi

AU - Li, Peixuan

AU - Ren, Ke

AU - He, Yixuan

AU - Gao, Xingyu

AU - Kou, Hongchao

AU - Wang, Jun

AU - Wang, Yiguang

AU - Song, Haifeng

AU - Liang, Xiubing

AU - Li, Jinshan

PY - 2024/4/15

Y1 - 2024/4/15

N2 - Innovative surfaces via lattice engineering are crucial challenges and critical to enhance the mechanical and functional properties of advanced materials. Here, a universal linear scaling rule in terms of key property parameters (KPPs) is proposed to estimate the modifications of local lattice strain (LLS) caused by the surface, in which the bulk modulus (B), the B/G ratio, and the bond energy are utilized to describe the KPPs of the BCC and FCC, the isotropic HCP, and the polarized A2B2O7-type Pyrochlore, individually. The modified broken-bond model by the Hook's law is addressed to predict the elastic-energy-corrected surface energy efficiently and precisely, which is capable to deal with the complex of geometry, chemistry, charge states of clean surface and are verified and validated in 28 metals and ceramics. While the LLS of metals is caused by the improved bond length, the ceramics one is yielded by the reduced one of polarized surface.

AB - Innovative surfaces via lattice engineering are crucial challenges and critical to enhance the mechanical and functional properties of advanced materials. Here, a universal linear scaling rule in terms of key property parameters (KPPs) is proposed to estimate the modifications of local lattice strain (LLS) caused by the surface, in which the bulk modulus (B), the B/G ratio, and the bond energy are utilized to describe the KPPs of the BCC and FCC, the isotropic HCP, and the polarized A2B2O7-type Pyrochlore, individually. The modified broken-bond model by the Hook's law is addressed to predict the elastic-energy-corrected surface energy efficiently and precisely, which is capable to deal with the complex of geometry, chemistry, charge states of clean surface and are verified and validated in 28 metals and ceramics. While the LLS of metals is caused by the improved bond length, the ceramics one is yielded by the reduced one of polarized surface.

KW - Broken-bond model

KW - Elastic energy

KW - Lattice engineering

KW - Surface energy

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U2 - 10.1016/j.scriptamat.2024.116026

DO - 10.1016/j.scriptamat.2024.116026

M3 - Article

AN - SCOPUS:85184999282

SN - 1359-6462

VL - 244

JO - Scripta Materialia

JF - Scripta Materialia

M1 - 116026

ER -

Hook's law scaled broken-bond model for surface energy: From metals to ceramics

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Keywords

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