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Liquid-infused nanostructured composite as a high-performance thermal interface material for effective cooling.


ABSTRACT: Effective heat dissipation remains a grand challenge for energy-dense devices and systems. As heterogeneous integration becomes increasingly inevitable in electronics, thermal resistance at interfaces has emerged as a critical bottleneck for thermal management. However, existing thermal interface solutions are constrained by either high thermal resistance or poor reliability. We report a strategy to create printable, high-performance liquid-infused nanostructured composites, comprising a mechanically soft and thermally conductive double-sided Cu nanowire array scaffold infused with a customized thermal-bridge liquid that suppresses contact thermal resistance. The liquid infusion concept is versatile for a broad range of thermal interface applications. Remarkably, the liquid metal infused nanostructured composite exhibits an ultra-low thermal resistance <1 mm² K W-1 at interface, outperforming state-of-the-art thermal interface materials on chip-cooling. The high reliability of the nanostructured composites enables undegraded performance through extreme temperature cycling. We envision liquid-infused nanostructured composites as a universal thermal interface solution for cooling applications in data centers, GPU/CPU systems, solid-state lasers, and LEDs.

SUBMITTER: Cheng R 

PROVIDER: S-EPMC11742011 | biostudies-literature | 2025 Jan

REPOSITORIES: biostudies-literature

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Liquid-infused nanostructured composite as a high-performance thermal interface material for effective cooling.

Cheng Rui R   Wang Qixian Q   Wang Zexiao Z   Jing Lin L   Garcia-Caraveo Ana V AV   Li Zhuo Z   Zhong Yibai Y   Liu Xiu X   Luo Xiao X   Huang Tianyi T   Yun Hyeong Seok HS   Salihoglu Hakan H   Russell Loren L   Kazem Navid N   Chen Tianyi T   Shen Sheng S  

Nature communications 20250118 1


Effective heat dissipation remains a grand challenge for energy-dense devices and systems. As heterogeneous integration becomes increasingly inevitable in electronics, thermal resistance at interfaces has emerged as a critical bottleneck for thermal management. However, existing thermal interface solutions are constrained by either high thermal resistance or poor reliability. We report a strategy to create printable, high-performance liquid-infused nanostructured composites, comprising a mechani  ...[more]

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