Connecting electronic entropy to empirically accessible electronic properties in high temperature systems

Author(s)

Rinzler, Charles Cooper; Allanore, Antoine

Abstract

A quantitative theoretical model connecting the thermopower and electronic entropy of molten systems is proposed, the validity of which is tested for semiconductors and metallic materials. The model accurately provides the entropy of mixing for molten semiconductors, as shown for the representative system Te–Tl. Predictions of the electronic entropy of fusion for compounds are in agreement with available data and offer a novel means to identify the correct electrical conductivity model when Hall measurements are not available. Electronic entropy for molten semiconductor and metallic systems is shown to reflect order in the molten and solid state. The model proves accurate at predicting the electronic state entropy contribution to the electronic entropy of mixing. Keywords: entropy; electronic entropy; thermopower; molten semiconductor

Date issued

2016-09

URI

http://hdl.handle.net/1721.1/114780

Department

Massachusetts Institute of Technology. Department of Materials Science and Engineering

Journal

Philosophical Magazine

Publisher

Taylor & Francis

Citation

Rinzler, Charles C., and Antoine Allanore. “Connecting Electronic Entropy to Empirically Accessible Electronic Properties in High Temperature Systems.” Philosophical Magazine 96, 29 (September 2016): 3041–3053 © 2016 Informa UK limited, trading as Taylor & Francis group

Version: Author's final manuscript

ISSN

1478-6435

1478-6443