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The role of polarizability in the interfacial thermal conductance at the gold–water interface

Hemanta Bhattarai, Kathie E. Newman, J. Daniel Gezelter

2020The Journal of Chemical Physics16 citationsDOI

Abstract

We have studied the interfacial thermal conductance, G, of the flat Au(111)-water interface using non-equilibrium molecular dynamics simulations. We utilized two metal models, one based on the embedded atom method (EAM) and the other including metallic polarizability via a density readjusting EAM. These were combined with three popular water models, SPC/E, TIP4P, and TIP4P-FQ, to understand the role of polarizability in the thermal transport process. A thermal flux was introduced using velocity shearing and scaling reverse non-equilibrium molecular dynamics, and transport coefficients were measured by calculating the resulting thermal gradients and temperature differences at the interface. Our primary finding is that the computed interfacial thermal conductance between a bare metal interface and water increases when polarizability is taken into account in the metal model. Additional work to understand the origin of the conductance difference points to changes in the local ordering of the water molecules in the first two layers of water above the metal surface. Vibrational densities of states on both sides of the interface exhibit interesting frequency modulation close to the surface but no obvious differences due to metal polarizability.

Topics & Concepts

PolarizabilityMolecular dynamicsThermalConductanceMetalChemistryWater modelChemical physicsAtom (system on chip)Thermal conductivityIntermolecular forceMaterials scienceMoleculeCondensed matter physicsThermodynamicsComputational chemistryPhysicsComposite materialEmbedded systemComputer scienceOrganic chemistryThermal properties of materialsnanoparticles nucleation surface interactionsSurface and Thin Film Phenomena
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