Mode transition of near-field radiative heat transfer between two subwavelength cylinders

IF 6.4 2区工程技术 Q1 MECHANICS

International Communications in Heat and Mass Transfer Pub Date : 2025-10-14 DOI:10.1016/j.icheatmasstransfer.2025.109863

Chengrong Zeng , Shuo Chen , Xiaohu Wu , Ceji Fu

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引用次数: 0

Abstract

Near-field radiative heat transfer (NFRHT) between nanostructures in the ‘dual nanoscale regime’ has attracted growing interest, especially the dramatic enhancement caused by corner and edge modes in the subwavelength coplanar membranes. However, when device geometry is further confined to subwavelength cylindrical structures — which sustain a rich set of localized electromagnetic multipolar surface modes along their sidewalls — the contributions of such modes to NFRHT remain unexplored. Here, we reveal that reducing nanostructure size drives a mode transition from surface phonon polaritons to multipolar surface modes and its effect on NFRHT between two axially aligned subwavelength silicon carbide (SiC) cylinders. When both radius and vacuum gap are significantly smaller than the thermal photon wavelength, multipolar surface modes can dominate the NFRHT. For 47-nm-radius, 400-nm-height SiC cylinders separated by a 100-nm vacuum gap, the radiative heat transfer coefficient reaches 1.53 times that of semi-infinite SiC plates at room temperature, exhibiting a 610-fold enhancement over the blackbody limit after accounting for geometric view factors. Further, the vacuum gap variation also induces the mode transition and a 2-fold enhancement relative to planar configurations can be achieved with a gap size of 50 nm. These findings provide critical insights into advancing nanoscale thermal management and energy harvesting applications.

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两个亚波长圆柱体间近场辐射换热的模态跃迁

在“双纳米体系”中，纳米结构之间的近场辐射传热（NFRHT）引起了越来越多的关注，特别是在亚波长共面膜中由角模式和边缘模式引起的显著增强。然而，当器件的几何结构进一步局限于亚波长圆柱形结构时——这种结构沿其侧壁维持着一组丰富的局域电磁多极表面模式——这些模式对NFRHT的贡献仍然未被探索。在这里，我们揭示了纳米结构尺寸的减小驱动了从表面声子极化到多极表面模式的模式转换，以及它对两个轴向排列的亚波长碳化硅（SiC）圆柱体之间NFRHT的影响。当半径和真空间隙都明显小于热光子波长时，多极表面模式可以主导NFRHT。对于半径为47 nm、高度为400 nm、真空间隙为100 nm的SiC圆柱体，室温下的辐射换热系数达到半无限SiC板的1.53倍，考虑几何视角因素后，比黑体极限提高了610倍。此外，真空间隙的变化也引起了模式的转变，当真空间隙尺寸为50 nm时，相对于平面结构可以实现2倍的增强。这些发现为推进纳米级热管理和能量收集应用提供了重要的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Communications in Heat and Mass Transfer 工程技术-力学

CiteScore

11.00

自引率

10.00%

发文量

648

审稿时长

32 days

期刊介绍： International Communications in Heat and Mass Transfer serves as a world forum for the rapid dissemination of new ideas, new measurement techniques, preliminary findings of ongoing investigations, discussions, and criticisms in the field of heat and mass transfer. Two types of manuscript will be considered for publication: communications (short reports of new work or discussions of work which has already been published) and summaries (abstracts of reports, theses or manuscripts which are too long for publication in full). Together with its companion publication, International Journal of Heat and Mass Transfer, with which it shares the same Board of Editors, this journal is read by research workers and engineers throughout the world.