Phonon-interference resonance effects in nanoparticles embedded in a matrix

Lei Feng, T. Shiga, Haoxue Han, S. Ju, Y. Kosevich, J. Shiomi
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引用次数: 19

Abstract

We report an unambiguous phonon resonance effect originating from germanium nanoparticles embedded in silicon matrix. Our approach features the combination of phonon wave-packet method with atomistic dynamics and finite element method rooted in continuum theory. We find that multimodal phonon resonance, caused by destructive interference of coherent lattice waves propagating through and around the nanoparticle, gives rise to sharp and significant transmittance dips, blocking the lower-end frequency range of phonon transport that is hardly diminished by other nanostructures. The resonance is sensitive to the phonon coherent length, where the finiteness of the wave packet width weakens the transmittance dip even when coherent length is longer than the particle diameter. Further strengthening of transmittance dips are possible by arraying multiple nanoparticles that gives rise to the collective vibrational mode. Finally, it is demonstrated that these resonance effects can significantly reduce thermal conductance in the lower-end frequency range.
嵌入在基质中的纳米颗粒中的声子干涉共振效应
我们报告了一个明确的声子共振效应起源于锗纳米颗粒嵌入硅基体。我们的方法将声子波包方法与原子动力学和基于连续介质理论的有限元方法相结合。我们发现,多模态声子共振是由穿过纳米粒子和围绕纳米粒子传播的相干晶格波的破坏性干涉引起的,导致透光率急剧下降,阻塞了其他纳米结构几乎不会减弱的声子传输的低端频率范围。共振对声子相干长度很敏感,即使相干长度大于粒子直径,波包宽度的有限性也会减弱透射率的下降。进一步加强透射率下降是可能的,通过排列多个纳米粒子,产生集体振动模式。最后,证明了这些共振效应可以显著降低低端频率范围内的热导率。
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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