Abstract

Based on the phonon Boltzmann transport equation under the relaxation time approximation, analytical expressions for the temperature profiles of both the steady state and modulated heat conduction inside a thin film deposited on a substrate are derived and analyzed. It is shown that these components of the temperature depend strongly on the ratio between the film thickness and the average phonon mean free path (MFP), and they exhibit the diffusive behavior as predicted by the Fourier's law of heat conduction when this ratio is much larger than unity. In contrast, in the ballistic regime when this ratio is comparable to or smaller than unity, the steady-state temperature tends to be independent of position, while the amplitude and the phase of the modulated temperature appear to be lower than those determined by the Fourier's law. Furthermore, we derive an invariant of heat conduction and a simple formula for the cross-plane thermal conductivity of dielectric thin films, which could be a useful guide for understanding and optimizing the thermal performance of the layered systems. This work represents the Boltzmann transport equation-based extension of the Rosencwaig and Gersho work [J. Appl. Phys. 47, 64 (1976)], which is based on the Fourier's law and has widely been used as the theoretical framework for the development of photoacoustic and photothermal techniques. This work might shed some light on developing a theoretical basis for the determination of the phonon MFP and relaxation time using ultrafast laser-based transient heating techniques.

Highlights

  • INTRODUCTIONUnder the steady-state conditions, the Boltzmann transport equation (BTE) has been solved numerically and applied to study the heat transport through a variety of layered systems and complex geometries.1,4,5,11,12

  • It has been shown that the phonon Boltzmann transport equation (BTE) is a more appropriate tool to describe the transport phenomena in nanostructured materials and during the ultrafast processes.4,6 Though great progresses have been made in solving the BTE for micro/nanoscale heat conduction, with significant efforts in recent years, the inherent difficulties associated with its solution have significantly limited the consideration of the size and transient effects

  • Given that our formula for the thermal conductivity has been derived rigorously from the analytical solution of the phonon BTE, its predictions are expected to be an extension of Majumdar model, which was inferred from numerical simulations

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Summary

INTRODUCTION

Under the steady-state conditions, the BTE has been solved numerically and applied to study the heat transport through a variety of layered systems and complex geometries.1,4,5,11,12 These works showed two main findings: (i) a reduction of the effective thermal conductivity with respect to their bulk values and (ii) the temperature profiles that differ significantly from those obtained using the Fourier’s law, due to the ballistic behavior of the energy carriers. Taking into account that the energy carriers travel ballistically without being deflected out of their propagation direction in a spatial scale in the order of one MFP, Chen proposed the ballistic-diffusive equations to study transient heat conduction from macro- to nanoscales.13,14 Even though this model presents good agreements with the predictions of the BTE for the heat conduction, it cannot be implemented. This work might shed some light on developing a theoretical basis for the determination of the phonon MFP and relaxation time using ultrafast laser-based transient thermoreflectance techniques

PHONON HEAT CONDUCTION IN A TWO-LAYER SYSTEM
Steady-state heat conduction
À E2ðkÞ
Modulated heat conduction
A B b2 C
Steady-state temperature profiles
Modulated temperature profiles
Findings
CONCLUSIONS

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