单晶硅片金刚石线锯的可持续评估：传统和电泳冷却策略

IF 1.9 Q3 ENGINEERING, MANUFACTURING

Manufacturing Letters Pub Date : 2025-01-05 DOI:10.1016/j.mfglet.2024.12.004

Eyob Messele Sefene , Chao-Chang A. Chen , Jin-Wei Yang

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引用次数: 0

摘要

在硅片生产中，追求金刚石线锯（DWS）的可持续发展对于减少环境影响和提高制造效率至关重要。然而，现有的锯切方法缺乏环保的冷却策略，在保持晶圆表面质量的同时降低能耗和二氧化碳排放。本文通过整合可加工性特征（如能耗、二氧化碳排放和表面粗糙度）来评估和提高可持续性，同时切片单晶硅（mono-Si）晶圆。采用传统的DWS （T-DWS）和电泳辅助反应（ER-DWS）冷却策略来评估和提高可持续性。结果表明，与T-DWS相比，ER-DWS比切削能量降低了14.16%，总二氧化碳排放量降低了9.22%，表面粗糙度（Ra）提高了8.78%。本研究通过在DWS过程中提出可持续的冷却策略来解决这一差距，为环保和高效的晶圆制造技术提供了见解。

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Sustainable assessment of diamond wire sawing for monocrystalline silicon wafers: Conventional and electrophoretic cooling strategies

Pursuing sustainable advancement in diamond wire sawing (DWS) is crucial for reducing environmental impact and improving manufacturing efficiency in silicon wafer production. However, the existing sawing methods lack eco-friendly cooling strategies that lower energy consumption and carbon dioxide (CO₂) emissions while maintaining wafer surface quality. This paper evaluates and improves sustainability by integrating machinability characteristics, such as energy consumption, CO₂ emissions, and surface roughness, while slicing monocrystalline silicon (mono-Si) wafers. Traditional DWS (T-DWS) and electrophoretic-assisted reactive (ER-DWS) cooling strategies were implemented to assess and enhance sustainability. Results demonstrate that ER-DWS achieves a 14.16 % reduction in specific cutting energy, a 9.22 % decrease in total CO₂ emissions, and an 8.78 % improvement in surface roughness (Ra) compared to T-DWS. This study addresses the gap by proposing a sustainable cooling strategy in the DWS process, providing insights into eco-friendly and efficient wafer manufacturing techniques.

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