Phonon branch-resolved electron-phonon coupling and the multitemperature model

Lu, Zexi; Vallabhaneni, Ajit K.; Cao, Bing-Yang; Ruan, Xiulin

doi:10.1103/physrevb.98.134309

Cited by 45 publications

(60 citation statements)

References 55 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…From a theoretical point of view, a few attempts have been presented to improve or simplify the TTM model [18,19]. Very recently [20], a more complex model was pointed out that replaced the standard TTM. The new model, named "Multiple-Temperature Model (MTM)", is more elaborated from theoretical point of view and provides a much better fitting of experimental data, e.g., in predicting the thermal field during laser-graphene interaction.…”

Section: Basic Statementmentioning

confidence: 99%

“…TTM uses the Quantum-Espresso package or/and EPW (Electron-Phonon coupling using Wannier functions) for simulations based on first principles density functional perturbation theory (DFPT) and an MTM [7]. The main goal of the current study is to develop a less sophisticated MTM using the Zhukovsky's formalism [20][21][22], thus producing innovation in current field.…”

Section: Basic Statementmentioning

confidence: 99%

See 1 more Smart Citation

An Analytical Multiple-Temperature Model for Flash Laser Irradiation on Single-Layer Graphene

et al. 2020

View full text Add to dashboard Cite

A Multiple-Temperature Model is proposed to describe the flash laser irradiation of a single layer of graphene. Zhukovsky’s mathematical approach is applied to solve the Fourier heat equations based upon quantum concepts, including heat operators. Easy solutions were inferred with respect to classical mathematics. Thus, simple equations were set for the electrons and phonon temperatures in the case of flash laser treatment of a single layer of graphene. Our method avoids the difficulties and extensive time-consuming nonequilibrium green function method or quantum field theories when applied in a condensed matter. Simple expressions were deduced that could prove useful for researchers.

show abstract

Section: Basic Statementmentioning

confidence: 99%

Section: Basic Statementmentioning

confidence: 99%

An Analytical Multiple-Temperature Model for Flash Laser Irradiation on Single-Layer Graphene

et al. 2020

View full text Add to dashboard Cite

show abstract

“…It is an analogy of the coupling T e-p lat using RTA based on the assumption that the phonon-phonon scattering has negligible effect on phonon distribution and phase space. is the G pp,i phonon-phonon coupling factor between phonon branch and the i scattering lattice reservoir, which is calculated using RTA from the following equation: [104][105][106][107] (14) where is the relaxation time of phonon branch , and the scattering τ i i lattice reservoir's temperature is defined to ensure the energy T lat transfer among phonon branches is conserved: (15) Then by solving numerically, we can obtain the transient Eq. 12and steady state temperature profile of the system with resolved electron and phonon branch temperatures.…”

Section: Multi-temperature Modelmentioning

confidence: 99%

“…In many applications, such as laser-matter interaction and hot electron cooling, electrons and phonons can be driven into strong non-equilibrium due to selective electronphonon ( ) coupling and phonon-phonon ( ) coupling, and their e-p p-p respective temperature profiles significantly deviate from each other. [11][12][13][14] This phenomenon can significantly affect the heat transfer processes such as hot electron relaxation and thermal measurements in experiments, and has been drawing attention among the research community in both experimental and theoretical areas in the recent decade.…”

Section: Introductionmentioning

confidence: 99%

Non-Equilibrium Thermal Transport: A Review of Applications and Simulation Approaches

Lu¹,

Ruan²

2019

ES Energy Environ.

Self Cite

View full text Add to dashboard Cite

As modern electronics shrink into nano-scale with increasing power consumption, thermal management inevitably becomes an important issue. Contrary to the conventional view of a single "apparent" temperature profile, electrons and different modes of phonons usually have different temperatures under many circumstances. This local thermal non-equilibrium appears widely in applications such as laser-matter interaction, hot electron cooling in solar cells, thermal transport across metal-insulator and semiconductor-semiconductor interfaces, etc. The resolved temperature profiles usually deviate significantly from the apparent temperature and have non-negligible effects on the measurement and interpretation of thermal properties and performance. Regardless, this phenomenon has been largely overlooked in early studies and has only started to attract attentions in the recent decades. In this work, we will review the background and research efforts on non-equilibrium thermal transport. The applications where non-equilibrium thermal transport is significant, and the corresponding simulation approaches, focused on two-temperature model, molecular dynamics, Boltzmann transport equations, and multi-temperature model, are reviewed.

show abstract

“…The MTM with e-p coupling has been introduced in our previous works. 16,30 In this work, we aim at predicting the effect of non-equilibrium thermal transport on lattice ITC, and therefore we only focus on the lattice portion. The governing equation is…”

Section: Theory and Governing Equationsmentioning

confidence: 99%

Role of phonon coupling and non-equilibrium near the interface to interfacial thermal resistance: The multi-temperature model and thermal circuit

Shi

Ruan

2019

Journal of Applied Physics

Self Cite

View full text Add to dashboard Cite

Interfacial thermal transport between two semi-infinite leads has been widely assumed to be independent from bulk transport in the two leads. However, here we show that due to the mismatch of phonon modal interfacial conductance and modal thermal conductivity, thermal interfacial transport is affected by the bulk thermal transport, and phonons near the interface can be driven into strong non-equilibrium, causing an additional resistance that is lumped into the interfacial resistance. This is captured using a multi-temperature model (MTM) that we introduce. Using thermal properties predicted from first-principles calculations and interfacial transmission coefficients predicted from the acoustic mismatch model, we present a case study of thermal transport across the Si-Ge interfaces using our MTM. The results show that phonon branches are in non-equilibrium near the interface due to energy redistribution caused by different thermal properties of the materials and the corresponding transmission coefficients, and the overall interfacial thermal conductance is 5.4% smaller than the conventional prediction, due to the phonon non-equilibrium resistance. We present a thermal circuit to include this new resistance due to phononphonon coupling and non-equilibrium near the interfaces. The thermal circuit also shows that increasing the phonon-phonon coupling factor G pp can reduce this resistance. Our MTM is a general and simple analytical approach expected to be useful for investigating the coupling between thermal transport across interfaces and in the bulk leads.

show abstract

Phonon branch-resolved electron-phonon coupling and the multitemperature model

Cited by 45 publications

References 55 publications

An Analytical Multiple-Temperature Model for Flash Laser Irradiation on Single-Layer Graphene

An Analytical Multiple-Temperature Model for Flash Laser Irradiation on Single-Layer Graphene

Non-Equilibrium Thermal Transport: A Review of Applications and Simulation Approaches

Role of phonon coupling and non-equilibrium near the interface to interfacial thermal resistance: The multi-temperature model and thermal circuit

Contact Info

Product

Resources

About