Direct measurement of room-temperature nondiffusive thermal transport over micron distances in a silicon membrane

Jeremy A. Johnson; A. A. Maznev; John Cuffe; Jeffrey K. Eliason; Austin J. Minnich; Timothy Kehoe; Clivia M.Sotomayor Torres; Gang Chen; Keith A. Nelson

doi:10.1103/PhysRevLett.110.025901

Direct measurement of room-temperature nondiffusive thermal transport over micron distances in a silicon membrane

Jeremy A. Johnson
, A. A. Maznev
, John Cuffe
, Jeffrey K. Eliason
, Austin J. Minnich
, Timothy Kehoe
, Clivia M.Sotomayor Torres
, Gang Chen
, Keith A. Nelson

School of Physics

Research output: Contribution to journal › Article › peer-review

Abstract

The "textbook" phonon mean free path of heat carrying phonons in silicon at room temperature is ∼40 nm. However, a large contribution to the thermal conductivity comes from low-frequency phonons with much longer mean free paths. We present a simple experiment demonstrating that room-temperature thermal transport in Si significantly deviates from the diffusion model already at micron distances. Absorption of crossed laser pulses in a freestanding silicon membrane sets up a sinusoidal temperature profile that is monitored via diffraction of a probe laser beam. By changing the period of the thermal grating we vary the heat transport distance within the range ∼1-10 μm. At small distances, we observe a reduction in the effective thermal conductivity indicating a transition from the diffusive to the ballistic transport regime for the low-frequency part of the phonon spectrum.

Original language	English
Article number	025901
Journal	Physical Review Letters
Volume	110
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevLett.110.025901
Publication status	Published - 8 Jan 2013

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10.1103/PhysRevLett.110.025901

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title = "Direct measurement of room-temperature nondiffusive thermal transport over micron distances in a silicon membrane",

abstract = "The {"}textbook{"} phonon mean free path of heat carrying phonons in silicon at room temperature is ∼40 nm. However, a large contribution to the thermal conductivity comes from low-frequency phonons with much longer mean free paths. We present a simple experiment demonstrating that room-temperature thermal transport in Si significantly deviates from the diffusion model already at micron distances. Absorption of crossed laser pulses in a freestanding silicon membrane sets up a sinusoidal temperature profile that is monitored via diffraction of a probe laser beam. By changing the period of the thermal grating we vary the heat transport distance within the range ∼1-10 μm. At small distances, we observe a reduction in the effective thermal conductivity indicating a transition from the diffusive to the ballistic transport regime for the low-frequency part of the phonon spectrum.",

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AU - Johnson, Jeremy A.

AU - Maznev, A. A.

AU - Cuffe, John

AU - Eliason, Jeffrey K.

AU - Minnich, Austin J.

AU - Kehoe, Timothy

AU - Torres, Clivia M.Sotomayor

AU - Chen, Gang

AU - Nelson, Keith A.

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N2 - The "textbook" phonon mean free path of heat carrying phonons in silicon at room temperature is ∼40 nm. However, a large contribution to the thermal conductivity comes from low-frequency phonons with much longer mean free paths. We present a simple experiment demonstrating that room-temperature thermal transport in Si significantly deviates from the diffusion model already at micron distances. Absorption of crossed laser pulses in a freestanding silicon membrane sets up a sinusoidal temperature profile that is monitored via diffraction of a probe laser beam. By changing the period of the thermal grating we vary the heat transport distance within the range ∼1-10 μm. At small distances, we observe a reduction in the effective thermal conductivity indicating a transition from the diffusive to the ballistic transport regime for the low-frequency part of the phonon spectrum.

AB - The "textbook" phonon mean free path of heat carrying phonons in silicon at room temperature is ∼40 nm. However, a large contribution to the thermal conductivity comes from low-frequency phonons with much longer mean free paths. We present a simple experiment demonstrating that room-temperature thermal transport in Si significantly deviates from the diffusion model already at micron distances. Absorption of crossed laser pulses in a freestanding silicon membrane sets up a sinusoidal temperature profile that is monitored via diffraction of a probe laser beam. By changing the period of the thermal grating we vary the heat transport distance within the range ∼1-10 μm. At small distances, we observe a reduction in the effective thermal conductivity indicating a transition from the diffusive to the ballistic transport regime for the low-frequency part of the phonon spectrum.

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Direct measurement of room-temperature nondiffusive thermal transport over micron distances in a silicon membrane

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