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Ultimate suppression of thermal transport in amorphous silicon nitride by phononic nanostructure.


ABSTRACT: Engineering the thermal conductivity of amorphous materials is highly essential for the thermal management of future electronic devices. Here, we demonstrate the impact of ultrafine nanostructuring on the thermal conductivity reduction of amorphous silicon nitride (a-Si3N4) thin films, in which the thermal transport is inherently impeded by the atomic disorders. Ultrafine nanostructuring with feature sizes below 20 nm allows us to fully suppress contribution of the propagating vibrational modes (propagons), leaving only the diffusive vibrational modes (diffusons) to contribute to thermal transport in a-Si3N4 A combination of the phonon-gas kinetics model and the Allen-Feldmann theory reproduced the measured results without any fitting parameters. The thermal conductivity reduction was explained as extremely strong diffusive boundary scattering of both propagons and diffusons. These findings give rise to substantial tunability of thermal conductivity of amorphous materials, which enables us to provide better thermal solutions in microelectronic devices.

SUBMITTER: Tambo N 

PROVIDER: S-EPMC7518865 | biostudies-literature | 2020 Sep

REPOSITORIES: biostudies-literature

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Ultimate suppression of thermal transport in amorphous silicon nitride by phononic nanostructure.

Tambo Naoki N   Liao Yuxuan Y   Zhou Chun C   Ashley Elizabeth Michiko EM   Takahashi Kouhei K   Nealey Paul F PF   Naito Yasuyuki Y   Shiomi Junichiro J  

Science advances 20200925 39


Engineering the thermal conductivity of amorphous materials is highly essential for the thermal management of future electronic devices. Here, we demonstrate the impact of ultrafine nanostructuring on the thermal conductivity reduction of amorphous silicon nitride (a-Si<sub>3</sub>N<sub>4</sub>) thin films, in which the thermal transport is inherently impeded by the atomic disorders. Ultrafine nanostructuring with feature sizes below 20 nm allows us to fully suppress contribution of the propagat  ...[more]

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