Issue 48, 2021

The onset of copper-ion mobility and the electronic transition in the kesterite Cu2ZnGeSe4

Abstract

Kesterite-related phases have attracted considerable interest as earth-abundant photovoltaic and thermoelectric materials. For the kesterite Cu2ZnGeSe4, we have established a direct link between anomalies in the temperature dependence of transport properties and an order-disorder transition. Powder neutron diffraction as a function of temperature reveals an order-disorder transition at 473 K, involving disordering of copper and zinc cations over three crystallographic positions. Vacancies are simultaneously created on the copper-ion sub-lattice, indicative of the concomitant onset of copper-ion mobility. Differential scanning calorimetry data show a weak thermal signature in this temperature region, typical of a second-order phase transition, which is consistent with the absence of anomalies in the temperature dependence of the unit cell volume. The partial melting of the copper-ion sub-lattice induces a transition in the electrical-transport properties. The changes in electrical resistivity and Seebeck coefficient suggest this involves a transition from a conventional, activated semiconductor, to a degenerate semiconductor. The entry of an increasing fraction of the copper-ion sub-lattice into a liquid-like state is reflected in a reduction in thermal conductivity above 473 K. The order-disorder phase transition identified here has consequences for the performance of photovoltaic and thermoelectric devices based on kesterites.

Graphical abstract: The onset of copper-ion mobility and the electronic transition in the kesterite Cu2ZnGeSe4

Supplementary files

Article information

Article type
Paper
Submitted
06 Oct 2021
Accepted
23 Nov 2021
First published
23 Nov 2021
This article is Open Access
Creative Commons BY license

J. Mater. Chem. A, 2021,9, 27493-27502

The onset of copper-ion mobility and the electronic transition in the kesterite Cu2ZnGeSe4

P. Mangelis, P. Vaqueiro, R. I. Smith and A. V. Powell, J. Mater. Chem. A, 2021, 9, 27493 DOI: 10.1039/D1TA08642A

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