Mechanisms of nonequilibrium electron-phonon coupling and thermal conductance at interfaces

Giri, Ashutosh; Gaskins, John T.; Donovan, Brian F.; Szwejkowski, Chester J.; Warzoha, Ronald J.; Rodriguez, Mark A.; Ihlefeld, Jon F.; Hopkins, Patrick E.

doi:10.1063/1.4914867

Cited by 82 publications

(118 citation statements)

References 63 publications

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“…To determine the size of the error bars, the FDTR-measured phase-lag vs. heating frequency data was fit to the heat diffusion equation to extract the deviations in G when At a metal-dielectric interface, electrons that carry heat within the metal transfer it to phonons that transmit the energy across the interface in a process known as electron-phonon coupling [41]. Electron-phonon coupling has been modeled as a thermal resistance process that is in series with the phonon energy transmission across the interface [42][43][44]. The values of G reported in Figure 2 represent the composite G due to the electron-phonon coupling conductance (G e-p ) and the phonon transmission conductance (G p ).…”

Section: Resultsmentioning

confidence: 99%

Thermal interface conductance across metal alloy–dielectric interfaces

Freedman

Davis

et al. 2016

Phys. Rev. B

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Section: Resultsmentioning

confidence: 99%

Thermal interface conductance across metal alloy–dielectric interfaces

Freedman

Davis

et al. 2016

Phys. Rev. B

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“…These pathways are i) metal electron–metal phonon coupling at the metal/nonmetal interface ( h e−mp ), ii) phonon–phonon coupling across the interface ( h p−p ), and iii) metal electron–nonmetal phonon coupling directly across the interface ( h e−nmp ). At a metal/nonmetal interface, electronic contributions to interfacial conductance have been mostly suggested to be nonexistent under equilibrium conditions . The interest in this topic was triggered by the seminal work from Stoner and Maris where they reported measurements of h K between a series of metals and nonmetals to which they compared with various phonon–phonon interface models and found discrepancies between theory and experiments .…”

Section: Effect Of Electron Scattering On Thermal Boundary Conductancementioning

confidence: 99%

“…However, recent theoretical works based on the two‐temperature model have suggested that strong electron–phonon coupling in the metal can lead to an increase in the phonon–phonon thermal conductance, while for weak electron–phonon coupling in the metal, this resistive pathway could become significant . There have also been several experimental works that have argued that under time scales where there is strong nonequilibrium between electrons and phonons in the metal, h e−nmp could potentially increase the rate of energy exchange at the interface . For example, Giri et al studied electron and phonon thermal coupling mechanisms at interfaces between gold films with and without Ti adhesion layers on various substrates via pump–probe technique.…”

Section: Effect Of Electron Scattering On Thermal Boundary Conductancementioning

confidence: 99%

A Review of Experimental and Computational Advances in Thermal Boundary Conductance and Nanoscale Thermal Transport across Solid Interfaces

Giri

Hopkins

2019

Adv Funct Materials

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207

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Interfacial thermal resistance is the primary impediment to heat flow in materials and devices as characteristic lengths become comparable to the mean‐free paths of the energy carriers. This thermal boundary conductance across solid interfaces at the nanoscale can affect a plethora of applications. The recent experimental and computational advances that have led to significant atomistic insights into the nanoscopic thermal transport mechanisms at interfaces between various types of materials are summarized. The authors focus on discussions of works that have pushed the limits to interfacial heat transfer and drastically increased the understanding of thermal boundary conductance on the atomic and nanometer scales near solid/solid interfaces. Specifically, the role of localized interfacial modes on the energy conversion processes occurring at interfaces is emphasized in this review. The authors also focus on experiments and computational works that have challenged the traditionally used phonon gas models in interpreting the physical mechanisms driving interfacial energy transport. Finally, the authors discuss the future directions and avenues of research that can further the knowledge of heat transfer across systems with broken symmetries.

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“…The notion of a surface oxidized membrane acting as an NPM—with the disordered oxygen atoms covering the membrane surface acting as the nanoresonators—was proposed by Xiong et al NPMs in the form of branched nanoribbon materials composed of molybdenum disulfide (MoS 2 ) were studied by Liu et al Giri and Hopkins and Yang and co‐workers extended the NPM concept to carbon nanotubes and graphene sheets, respectively. Another intriguing NPM architecture is based on a graphene sheet with branching fullerene nanoresonators . Other than thermal conductivity reduction, the impact of nanopillars on the heat capacity was investigated by Iskander et al using both theory and experiments .…”

Section: Thermal Transport In Nanostructured Membranesmentioning

confidence: 99%

Thermal Conductivity Reduction in a Nanophononic Metamaterial versus a Nanophononic Crystal: A Review and Comparative Analysis

Hussein

Tsai

Honarvar

2019

Adv Funct Materials

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The notion of a locally resonant metamaterial—widely applied to light and sound—has recently been introduced to heat, whereby the thermal conductivity is reduced primarily by intrinsic localized atomic vibrations rather than scattering mechanisms. This article reviews and analyzes this new emerging concept, termed nanophononic metamaterial (NPM), and contrasts it with the competing concept of a nanophononic crystal (NPC) in which thermal conductivity reduction is realized primarily via nanoscale Bragg scattering. Both the NPM and NPC core mechanisms require the presence of a sufficient level of wave behavior, which is possible when there is a relatively wide distribution of the phonon mean free path (MFP). Silicon serves as a perfect material to form NPMs and NPCs given its relatively large average phonon MFP. This offers a unique opportunity considering silicon's abundance and mature fabrication technology. It is shown in this comparative study that while both the NPM and NPC nanosystems may be rendered to serve as extreme insulators of heat, an NPM may do so without excessive reduction in the minimum feature size–which is key to keeping the electrical properties intact. This trait makes a silicon‐based NPM poised to serve as a low‐cost thermoelectric material with exceptional performance.

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Mechanisms of nonequilibrium electron-phonon coupling and thermal conductance at interfaces

Cited by 82 publications

References 63 publications

Thermal interface conductance across metal alloy–dielectric interfaces

Thermal interface conductance across metal alloy–dielectric interfaces

A Review of Experimental and Computational Advances in Thermal Boundary Conductance and Nanoscale Thermal Transport across Solid Interfaces

Thermal Conductivity Reduction in a Nanophononic Metamaterial versus a Nanophononic Crystal: A Review and Comparative Analysis

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