The influence of interface bonding on thermal transport through solid–liquid interfaces

Harikrishna, Hari; Ducker, William A.; Huxtable, Scott T.

doi:10.1063/1.4812749

Cited by 99 publications

(126 citation statements)

References 28 publications

(40 reference statements)

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“…Ge et al 18 experimentally measured the thermal boundary conductance across Au/water and Al/water interfaces with self-assembled monolayers to vary the degree of hydrophobicity; their measurements show that hydrophilic interfaces have higher thermal boundary conductances than hydrophobic interfaces. Similar measurements across Au/water interfaces were recently reported by Harikrishna et al, 19 and they linked the thermal boundary conductance to the work of adhesion at the interface, directly relating the bonding at the interface to the thermal boundary conductance.…”

Section: Background: Solid/liquid Thermal Couplingsupporting

confidence: 81%

“…[6][7][8][9][10][11][12][13][14][15][16][17] However, experimental measurements of the thermal boundary conductance across planar solid and a liquid interfaces (i.e., not nanofluids) at non-cryogenic temperatures are limited. 18,19 Although a wealth of molecular dynamics (MD) simulations have elucidated physical processes at solid/liquid interfaces, a void still exists in terms of analytical modeling of thermal transport across solid/liquid interfaces to parallel that which exists across solid/solid a) M. E. Caplan and A. Giri contributed equally to this work. b) Electronic mail: phopkins@virginia.edu interfaces.…”

Section: Introductionmentioning

confidence: 99%

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Analytical model for the effects of wetting on thermal boundary conductance across solid/classical liquid interfaces

Caplan

Giri

Hopkins

2014

The Journal of Chemical Physics

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Section: Background: Solid/liquid Thermal Couplingsupporting

confidence: 81%

Section: Introductionmentioning

confidence: 99%

Analytical model for the effects of wetting on thermal boundary conductance across solid/classical liquid interfaces

Caplan

Giri

Hopkins

2014

The Journal of Chemical Physics

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“…Here, we use a semi-empirical model to account for the effect of nanostructures on Kapitza resistance. Both experiments and atomic simulations suggest a linear relation between the interfacial thermal conductance (i.e., R À1 K ) and the solid-liquid interaction energy per unit area [31,39,40] that scales linearly with the Wenzel roughness ratio, following R À1 K / r. By fitting the MD results for the Kapitza resistance at a water-gold interface [32] (see Fig. 3), it follows…”

Section: The Modelmentioning

confidence: 90%

“…Furthermore, existing thin film evaporation models neglected the Kapitza resistance, i.e., the interfacial thermal resistance caused by the mismatch in thermal properties between two contact materials. It is important to note that the Kapitza resistance at a water-gold interface is $10 À8 m 2 K/W [31,32], equivalent to the conduction resistance of a 10 nm water film. As the non-evaporating water film becomes as thin as a few nanometers [25], the Kapitza resistance, which is significantly affected by nanostructures, becomes nontrivial [32,33].…”

Section: Introductionmentioning

confidence: 99%

Effect of nanostructures on heat transfer coefficient of an evaporating meniscus

Sun

2016

International Journal of Heat and Mass Transfer

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a b s t r a c tThe effect of nanostructures on heat transfer coefficient of an evaporating meniscus in thin film evaporation and nucleate boiling is investigated using combined modeling and molecular dynamics (MD) simulations. The model is developed accounting for the evaporation kinetics, disjoining pressure, conduction resistance, and Kapitza resistance of an evaporating meniscus on a nanostructured surface. The model is then verified using MD simulations for a water-gold system with square nanostructures of varying depth and film thickness. Good agreement is obtained between MD results and model predictions. The results show the existence of a critical film thickness on the order of a few nanometers where the heat transfer coefficient reaches its maximum. For a film thickness below this critical value, the evaporation resistance dominates and the heat transfer coefficient increases with film thickness but decreases with nanostructure depth due to the enhanced disjoining pressure. However, for a film thickness greater than the critical value, the conduction resistance dominates and the heat transfer coefficient decreases with film thickness but increases with nanostructure depth. In addition, both critical film thickness and maximum heat transfer coefficient increase with the roughness ratio of the nanostructure, mainly due to the reduction in Kapitza resistance.

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“…The transfer of vibrational energy between liquids and solids is, however, poorly understood compared to solid-solid interfaces, in part due to the difficulty of experimentally isolating the thermal resistance of the interface [7,8]. Existing experiments have, however, indicated [8][9][10][11][12] that the interfacial conductance of a typical solid-liquid surface is generally close to the conductance of a typical solid-solid interface.…”

Section: Introductionmentioning

confidence: 99%

Spectral mapping of heat transfer mechanisms at liquid-solid interfaces

et al. 2016

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Thermal transport through liquid-solid interfaces plays an important role in many chemical and biological processes, and better understanding of liquid-solid energy transfer is expected to enable improving the efficiency of thermally driven applications. We determine the spectral distribution of thermal current at liquid-solid interfaces from nonequilibrium molecular dynamics, delivering a detailed picture of the contributions of different vibrational modes to liquid-solid energy transfer. Our results show that surface modes located at the Brillouin zone edge and polarized along the liquidsolid surface normal play a crucial role in liquid-solid energy transfer. Strong liquid-solid adhesion allows also for the coupling of in-plane polarized modes in the solid with the liquid, enhancing the heat transfer rate and enabling efficient energy transfer up to the cut-off frequency of the solid. Our results provide fundamental understanding of the energy transfer mechanisms in liquid-solid systems and enable detailed investigations of energy transfer between, e.g., water and organic molecules.

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The influence of interface bonding on thermal transport through solid–liquid interfaces

Cited by 99 publications

References 28 publications

Analytical model for the effects of wetting on thermal boundary conductance across solid/classical liquid interfaces

Analytical model for the effects of wetting on thermal boundary conductance across solid/classical liquid interfaces

Effect of nanostructures on heat transfer coefficient of an evaporating meniscus

Spectral mapping of heat transfer mechanisms at liquid-solid interfaces

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