烧结
铜
纳米颗粒
电力电子
数码产品
材料科学
纳米技术
冶金
功率(物理)
光电子学
电气工程
工程类
热力学
物理
标识
DOI:10.23919/icep-iaac64884.2025.11003018
摘要
As power electronics continue to advance, the demand for cost-effective and highly reliable interconnection materials has increased. Sintered metal nanoparticles, particularly copper (Cu), have gained attention as a promising alternative to lead-free solder due to their high electrical and thermal conductivity. However, conventional sintering processes often require high temperatures and reducing atmospheres, which limit their applicability in industrial settings. This study investigates the low-temperature sintering of slightly oxidized copper nanoparticles (Cux O-NPs: X = 64 or 8) under cost-effective and practical conditions. We developed a novel approach that utilizes a mild reducing agent combined with a controlled sintering atmosphere to achieve efficient densification at temperatures below 200°C. By optimizing the nanoparticle size, oxidation state, and sintering conditions, we successfully improved the mechanical properties of the sintered Cu structures. The sintered Cu demonstrated a resistivity close to that of bulk copper and exhibited excellent adhesion, making it suitable for power electronic applications. Furthermore, this low-temperature process eliminates the need for expensive reducing environments such as hydrogen gas, significantly reducing manufacturing costs and enhancing process safety. The proposed sintering approach is highly attractive for next-generation electronic packaging and interconnections.
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