Structurally engineered heat loss suppression in nanogap-aligned nanowires for power efficient heating.

IF 4.6 3区材料科学 Q2 CHEMISTRY, MULTIDISCIPLINARY Nanoscale Advances Pub Date : 2025-02-11 DOI:10.1039/d4na00894d

Min-Seung Jo, Beom-Jun Kim, Myung-Kun Chung, Se-Yoon Jung, Min-Ho Seo, Jae-Young Yoo, Jae-Soon Yang, Sung-Ho Kim, Jun-Bo Yoon

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Abstract

Thermal management at the nanoscale offers potential advancements in power-efficient geometrical design; however, both conduction- and convection-based structural optimization have yet to be fully investigated due to dimensional limitations. In this study, we analytically designed a structured configuration within a regime comparable to the mean free path of heat-transferring carriers. The optimally designed nanowire configuration, featuring aligned nanowires with narrow gaps (∼22 nm), was designed based on the analytic calculation. A tailored nanofabrication technique enabled a reliable geometrical parametric study, experimentally validating the proposed theoretical design. Finally, by engineering both conduction heat loss and air molecular interactions in convective heat loss at the nanoscale, we suggest an optimized heater for atmospheric conditions based on scaling factor-induced thermophysical properties, surpassing the efficiency of traditional film-based heaters.

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纳米尺度的热管理为高能效几何设计提供了潜在的进步；然而，由于尺寸限制，基于传导和对流的结构优化尚未得到充分研究。在本研究中，我们在与传热载流子平均自由路径相当的范围内分析设计了一种结构配置。在分析计算的基础上，我们设计出了具有窄间隙（∼22 nm）的排列整齐的纳米线配置。量身定制的纳米制造技术实现了可靠的几何参数研究，从实验上验证了所提出的理论设计。最后，通过在纳米尺度上设计传导热损失和对流热损失中的空气分子相互作用，我们提出了一种基于缩放因子诱导的热物理性质的大气条件下的优化加热器，其效率超过了传统的基于薄膜的加热器。

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