Effect of nanosilica abrasive properties on tungsten chemical mechanical planarization

The effect of particle size, solid content, and surface charge of nano-silica on tungsten chemical mechanical polishing was explored to clarify the mechanical action. Particle size and solid content both showed a linear relationship with tungsten material removal rate. Analyzed with coefficient fric...

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Published in:Journal of materials science. Materials in electronics 2024-02, Vol.35 (5), p.338, Article 338
Main Authors: Zhang, Jingwei, Ren, Gaoyuan, Wang, Li, Xie, Wenxiang, Pan, Deng, Su, Hongjiu, Wang, Shudong
Format: Article
Language:English
Subjects:
Abrasives
Characterization and Evaluation of Materials
Chemical-mechanical polishing
Chemistry and Materials Science
Coefficient of friction
Coupling agents
Friction
Material removal rate (machining)
Materials Science
Optical and Electronic Materials
Particle size
Silicon dioxide
Substrates
Surface charge
Tungsten
Zeta potential
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container_issue 5
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container_title Journal of materials science. Materials in electronics
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creator Zhang, Jingwei
Ren, Gaoyuan
Wang, Li
Xie, Wenxiang
Pan, Deng
Su, Hongjiu
Wang, Shudong
description The effect of particle size, solid content, and surface charge of nano-silica on tungsten chemical mechanical polishing was explored to clarify the mechanical action. Particle size and solid content both showed a linear relationship with tungsten material removal rate. Analyzed with coefficient friction during the process, the contact area and contact mode changed with the varying particle size and solid content. In addition, the different surface charge of nano-silica was prepared through a graft of different silane coupling agent. The positively charged A-Surf-silica improved the tungsten removal rate by 33.2% and also presented higher coefficient friction in the polishing process. Moreover, tungsten removal rate shows a linear positive correlation to the abrasives’ zeta potential. The mechanism of abrasives in tungsten chemical mechanical planarization is discussed by combining DLVO theory and coefficient friction through the contact area, contact mode, and the synergy between the abrasives and the substrate of the mechanical action.
doi_str_mv 10.1007/s10854-023-11914-5
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subjects Abrasives
Characterization and Evaluation of Materials
Chemical-mechanical polishing
Chemistry and Materials Science
Coefficient of friction
Coupling agents
Friction
Material removal rate (machining)
Materials Science
Optical and Electronic Materials
Particle size
Silicon dioxide
Substrates
Surface charge
Tungsten
Zeta potential
title Effect of nanosilica abrasive properties on tungsten chemical mechanical planarization
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