Analytical modeling of ground surface topography in monocrystalline silicon grinding considering the ductile-regime effect

Hao Nan Li; Tian Biao Yu; Li Da Zhu; Wan Shan Wang

doi:10.1016/j.acme.2017.03.010

Analytical modeling of ground surface topography in monocrystalline silicon grinding considering the ductile-regime effect

Hao Nan Li, Tian Biao Yu, Li Da Zhu, Wan Shan Wang

Research output: Journal Publication › Article › peer-review

50 Citations (Scopus)

Abstract

Grinding process of monocrystalline silicon easily leads to fractured surfaces, therefore an analytical model of the ground silicon surface is presented. In the model, the ductile-regime effect is considered by determining grain-workpiece interaction mode (ductile and brittle modes) at each grinding moment. Validation experiments proved that the model can, to a large extent, describe realistic silicon grinding and predict the machined surfaces in terms of (i) brittle and ductile area, (ii) roughness and waviness, and (iii) potential chipping zone sizes. The model therefore is anticipated to be not only meaningful to guide and optimize the industrial silicon grinding process, but also transferable to other kinds of brittle materials.

Original language	English
Pages (from-to)	880-893
Number of pages	14
Journal	Archives of Civil and Mechanical Engineering
Volume	17
Issue number	4
DOIs	https://doi.org/10.1016/j.acme.2017.03.010
Publication status	Published - 1 Sept 2017
Externally published	Yes

Keywords

Analytical model
Grinding
Silicon
Surface topography

ASJC Scopus subject areas

Civil and Structural Engineering
Mechanical Engineering

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10.1016/j.acme.2017.03.010

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title = "Analytical modeling of ground surface topography in monocrystalline silicon grinding considering the ductile-regime effect",

abstract = "Grinding process of monocrystalline silicon easily leads to fractured surfaces, therefore an analytical model of the ground silicon surface is presented. In the model, the ductile-regime effect is considered by determining grain-workpiece interaction mode (ductile and brittle modes) at each grinding moment. Validation experiments proved that the model can, to a large extent, describe realistic silicon grinding and predict the machined surfaces in terms of (i) brittle and ductile area, (ii) roughness and waviness, and (iii) potential chipping zone sizes. The model therefore is anticipated to be not only meaningful to guide and optimize the industrial silicon grinding process, but also transferable to other kinds of brittle materials.",

keywords = "Analytical model, Grinding, Silicon, Surface topography",

author = "Li, {Hao Nan} and Yu, {Tian Biao} and {Da Zhu}, Li and Wang, {Wan Shan}",

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doi = "10.1016/j.acme.2017.03.010",

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T1 - Analytical modeling of ground surface topography in monocrystalline silicon grinding considering the ductile-regime effect

AU - Li, Hao Nan

AU - Yu, Tian Biao

AU - Da Zhu, Li

AU - Wang, Wan Shan

PY - 2017/9/1

Y1 - 2017/9/1

N2 - Grinding process of monocrystalline silicon easily leads to fractured surfaces, therefore an analytical model of the ground silicon surface is presented. In the model, the ductile-regime effect is considered by determining grain-workpiece interaction mode (ductile and brittle modes) at each grinding moment. Validation experiments proved that the model can, to a large extent, describe realistic silicon grinding and predict the machined surfaces in terms of (i) brittle and ductile area, (ii) roughness and waviness, and (iii) potential chipping zone sizes. The model therefore is anticipated to be not only meaningful to guide and optimize the industrial silicon grinding process, but also transferable to other kinds of brittle materials.

AB - Grinding process of monocrystalline silicon easily leads to fractured surfaces, therefore an analytical model of the ground silicon surface is presented. In the model, the ductile-regime effect is considered by determining grain-workpiece interaction mode (ductile and brittle modes) at each grinding moment. Validation experiments proved that the model can, to a large extent, describe realistic silicon grinding and predict the machined surfaces in terms of (i) brittle and ductile area, (ii) roughness and waviness, and (iii) potential chipping zone sizes. The model therefore is anticipated to be not only meaningful to guide and optimize the industrial silicon grinding process, but also transferable to other kinds of brittle materials.

KW - Analytical model

KW - Grinding

KW - Silicon

KW - Surface topography

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DO - 10.1016/j.acme.2017.03.010

M3 - Article

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SN - 1644-9665

VL - 17

SP - 880

EP - 893

JO - Archives of Civil and Mechanical Engineering

JF - Archives of Civil and Mechanical Engineering

IS - 4

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Analytical modeling of ground surface topography in monocrystalline silicon grinding considering the ductile-regime effect

Abstract

Keywords

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