Reliability of Raman measurements of thermal conductivity of single-layer graphene due to selective electron-phonon coupling: A first-principles study

Vallabhaneni, Ajit K.; Singh, Dhruv; Bao, Hua; Murthy, Jayathi Y.; Ruan, Xiulin

doi:10.1103/physrevb.93.125432

Cited by 109 publications

(110 citation statements)

References 33 publications

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“…While most PBTE studies used IFCs from first-principles as inputs and tried to match the measured experimental data, we employ the empirical potential to generate the interatomic force constants. This is because the thermal conductivity measurements on two-dimensional materials are still quite challenging and there is still no consensus on the accuracy of the existing measurement methods [42]. Instead, using the empirical potential, we could compare the results from PBTE studies with the thermal conductivity predictions made by MD simulations directly, and identify the influence of four-phonon scatterings and temperature dependent IFCs on phonon transport in graphene.…”

Section: Introductionmentioning

confidence: 99%

Revisiting phonon-phonon scattering in single-layer graphene

Fan

Bao

et al. 2019

Phys. Rev. B

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Understanding the mechanisms of thermal conduction in graphene is a long-lasting research topic, due to its high thermal conductivity. Peierls-Boltzmann transport equation (PBTE) based studies have revealed many unique phonon transport properties in graphene, but most previous works only considered three-phonon scatterings and relied on interatomic force constants (IFCs) extracted at 0 K. In this paper, we explore the roles of four-phonon scatterings and the temperature dependent IFCs on phonon transport in graphene through our PBTE calculations. We demonstrate that the strength of four-phonon scatterings would be severely overestimated by using the IFCs extracted at 0 K compared with those corresponding to a finite temperature, and four-phonon scatterings are found to significantly reduce the thermal conductivity of graphene even at room temperature. In order to reproduce the prediction from molecular dynamics simulations, phonon frequency broadening has to be taken into account when determining the phonon scattering rates.Our study elucidates the phonon transport properties of graphene at finite temperatures, and could be extended to other crystalline materials.

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Section: Introductionmentioning

confidence: 99%

Revisiting phonon-phonon scattering in single-layer graphene

Fan

Bao

et al. 2019

Phys. Rev. B

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“…Electron-phonon (e-p) coupling is an important physical phenomenon that affects Joule heating, laser-matter interaction, and hot electron relaxation [1][2][3][4][5][6][7][8]. A thorough understanding of e-p coupling is crucial for researching material properties as well as advancing the electronic device technology.…”

Section: Introductionmentioning

confidence: 99%

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

Vallabhaneni

Cao

et al. 2018

Phys. Rev. B

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Electron-phonon (e-p) interaction and transport are important for laser-matter interactions, hot-electron relaxation, and metal-nonmetal interfacial thermal transport. A widely used approach is the two-temperature model (TTM), where e-p coupling is treated with a gray approach with a lumped coupling factor G ep and the assumption that all phonons are in local thermal equilibrium. However, in many applications, different phonon branches can be driven into strong nonequilibrium due to selective e-p coupling, and a TTM analysis can lead to misleading or wrong results. Here, we extend the original TTM into a general multitemperature model (MTM), by using phonon branch-resolved e-p coupling factors and assigning a separate temperature for each phonon branch. The steady-state thermal transport and transient hot electron relaxation processes in constant and pulse laser-irradiated single-layer graphene (SLG) are investigated using our MTM respectively. Results show that different phonon branches are in strong nonequilibrium, with the largest temperature rise being more than six times larger than the smallest one. A comparison with TTM reveals that under steady state, MTM predicts 50% and 80% higher temperature rises for electrons and phonons respectively, due to the "hot phonon bottleneck" effect. Further analysis shows that MTM will increase the predicted thermal conductivity of SLG by 67% and its hot electron relaxation time by 60 times. We expect that our MTM will prove advantageous over TTM and gain use among experimentalists and engineers to predict or explain a wide ranges of processes involving laser-matter interactions.

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“…Any wrong calculation of these two factors could result in a significant systematic error. The first one has been known for many years, however, the second one has only been investigated very recently by Vallabhaneni et al (Vallabhaneni, et al, 2016). In their detailed computational study, Vallabhaneni et al pointed out that the ZA and ZO phonons that contribute the most to the thermal conductivity of single layer graphene are indeed out of thermal equilibrium.…”

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confidence: 99%

Colloquium: Phononic thermal properties of two-dimensional materials

et al. 2018

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Following the emergence of many novel two-dimensional (2-D) materials beyond graphene, interest has grown in exploring implications for fundamental physics and practical applications, ranging from electronics, photonics, phononics, to thermal management and energy storage. In this Colloquium, we first summarize and compare the phonon properties, such as phonon dispersion and relaxation time, of pristine 2-D materials with single layer graphene to understand the role of crystal structure and dimension on thermal conductivity. We then compare the phonon properties, contrasting idealized 2-D crystals, realistic 2-D crystals, and 3-D crystals, and synthesizing this to develop a physical picture of how the sample size of 2-D materials affects their thermal conductivity. The effects of geometry, such as number of layers, and nanoribbon width, together with the presence of defects, mechanical strain, and substrate interactions, on the thermal properties of 2-D materials are discussed. Intercalation affects both the group velocities and phonon relaxation times of layered crystals and thus tunes the thermal conductivity along 2 both the through-plane and basal-plane directions. We conclude with a discussion of the challenges in theoretical and experimental studies of thermal transport in 2-D materials. The rich and special phonon physics in 2-D materials make them promising candidates for exploring novel phenomena such as topological phonon effects and applications such as phononic quantum devices.

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Reliability of Raman measurements of thermal conductivity of single-layer graphene due to selective electron-phonon coupling: A first-principles study

Cited by 109 publications

References 33 publications

Revisiting phonon-phonon scattering in single-layer graphene

Revisiting phonon-phonon scattering in single-layer graphene

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

Colloquium: Phononic thermal properties of two-dimensional materials

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