铜
材料科学
纳米
箔法
热稳定性
纳米尺度
数码产品
纳米技术
冶金
热的
金属
晶粒生长
粒度
纳米电子学
纳米颗粒
电阻率和电导率
柔性电子器件
复合材料
导电体
光电子学
储能
热导率
工程物理
作者
Zhao Cheng,L LIU,Zhiyang Yu,Xiaoyuan Ye,N.R. Tao,Ting Zhu,Lei Lu
出处
期刊:Science
[American Association for the Advancement of Science]
日期:2026-04-16
卷期号:392 (6795): 275-279
标识
DOI:10.1126/science.aed7758
摘要
The development of copper foils that simultaneously exhibit ultrahigh strength, high electrical conductivity, and thermal stability remains a major challenge for advanced electronics and energy storage systems. We report a 10-micrometer-thick copper foil featuring nanoscale grains and periodically distributed gradient super-nano domains (approximately 3 nanometers in size) throughout its thickness that was produced by an industrially scalable electrodeposition process. This copper foil demonstrates a combination of approximately 900-megapascal tensile strength, 90% standard electrical conductivity, and exceptional thermal stability. These superior properties originate from a dual strengthening-stabilization mechanism in which the periodically distributed super-nano domains both enhance strength and stabilize grain boundaries. This strategy not only advances copper foil technology but also provides a general design pathway for developing other scalable, high-performance metallic materials.
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