六方氮化硼
材料科学
声子
极化子
超短脉冲
光电子学
凝聚态物理
化学物理
纳米技术
石墨烯
光学
物理
激光器
作者
William Hutchins,Saman Zare,Dan M. Hirt,John A. Tomko,Joseph R. Matson,Katja Diaz‐Granados,Mackey Long,Mingze He,Thomas W. Pfeifer,Jiahan Li,James H. Edgar,Jon‐Paul Maria,Joshua D. Caldwell,Patrick E. Hopkins
出处
期刊:Nature Materials
[Nature Portfolio]
日期:2025-03-17
卷期号:24 (5): 698-706
被引量:21
标识
DOI:10.1038/s41563-025-02154-5
摘要
Thermal transport across solid–solid interfaces is vital for advanced electronic and photonic applications, yet conventional conduction pathways often restrict performance. In polar crystals, hybridized vibrational modes called phonon polaritons offer a promising avenue to overcome the limitations of intrinsic phonon heat conduction. Here our work demonstrates that volume-confined hyperbolic phonon polariton (HPhP) modes can transfer energy across solid–solid interfaces at rates far exceeding phonon–phonon conduction. Using pump–probe thermoreflectance with a mid-infrared, tunable probe pulse with subpicosecond resolution, we remotely and selectively observe HPhP modes in hexagonal boron nitride (hBN) via broadband radiative heating from a gold source. Our measurements ascertain that hot electrons impinging at the interface radiate directly into the HPhPs of hBN in the near field, bypassing the phonon–phonon transport pathway. Such polaritonic coupling enables thermal transport speeds in solids orders of magnitude faster than possible through diffusive phonon processes. We thereby showcase a pronounced thermal transport enhancement across the gold–hBN interface via phonon–polariton coupling, advancing the limits of interfacial heat transfer. The authors report subnanosecond thermal transport on a gold–hexagonal boron nitrite interface governed by hyperbolic phonon–polariton coupling, demonstrating a cooling mechanism orders of magnitude faster than those relying on phonon-mediated processes.
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