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Temperature dependent elastic constants and thermodynamic properties of BAs: An <i>ab initio</i> investigation

Cristiano Malica, Andrea Dal Corso

2020Journal of Applied Physics27 citationsDOIOpen Access PDF

Abstract

We present an ab initio study of the temperature dependent elastic constants of boron arsenide, a semiconductor that exhibits ultra-high thermal conductivity and is under investigation for thermal management in electronics. We test the consistency of our predictions by computing the temperature dependent sound velocity of the longitudinal acoustic mode along the [111] direction and comparing with experiments. Furthermore, as a by-product, we present the room temperature phonon dispersions and the temperature dependent thermal expansion, isobaric heat capacity, and average Grüneisen parameter compared with the most updated experiments and previous calculations when available. Finally, we present the theoretical estimate of the temperature dependent mean square atomic displacements.

Topics & Concepts

ThermodynamicsIsobaric processThermal conductivityPhononMaterials scienceThermalAb initioWork (physics)Condensed matter physicsGrüneisen parameterConsistency (knowledge bases)Ab initio quantum chemistry methodsSpecific heatTemperature measurementHeat capacityMaterial propertiesConstant (computer programming)BoronSemiconductorSpeed of soundThermal expansionThermodynamic temperatureAtmospheric temperature rangeRoot mean squareNormal modeMode (computer interface)ChemistryElasticity (physics)Square (algebra)Thermal properties of materialsBoron and Carbon Nanomaterials ResearchAdvanced Thermoelectric Materials and Devices
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