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Room Temperature Lattice Thermal Conductivity of GeSn Alloys

Omar Concepción, Jhonny Tiscareño-Ramírez, Ada Angela Chimienti, Thomas Classen, Agnieszka Anna Corley‐Wiciak, Andrea Tomadin, Davide Spirito, Dario Pisignano, Patrizio Graziosi, Z. Ikonić, Qing‐Tai Zhao, Detlev Grützmacher, Giovanni Capellini, Stefano Roddaro, Michele Virgilio, Dan Buca

2024ACS Applied Energy Materials21 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide CMOS-compatible materials for efficient energy harvesters at temperatures characteristic for on-chip operation and body temperature are the key ingredients for sustainable green computing and ultralow power Internet of Things applications. In this context, the lattice thermal conductivity (κ) of new group IV semiconductors, namely Ge 1– x Sn x alloys, are investigated. Layers featuring Sn contents up to 14 at.% are epitaxially grown by state-of-the-art chemical-vapor deposition on Ge buffered Si wafers. An abrupt decrease of the lattice thermal conductivity (κ) from 55 W/(m·K) for Ge to 4 W/(m·K) for Ge 0.88 Sn 0.12 alloys is measured electrically by the differential 3ω-method. The thermal conductivity was verified to be independent of the layer thickness for strained relaxed alloys and confirms the Sn dependence observed by optical methods previously. The experimental κ values in conjunction with numerical estimations of the charge transport properties, able to capture the complex physics of this quasi-direct bandgap material system, are used to evaluate the thermoelectric figure of merit ZT for n- and p-type GeSn epitaxial layers. The results highlight the high potential of single-crystal GeSn alloys to achieve similar energy harvest capability as already present in SiGe alloys but in the 20 °C–100 °C temperature range where Si-compatible semiconductors are not available. This opens the possibility of monolithically integrated thermoelectric on the CMOS platform.

Topics & Concepts

Materials scienceThermoelectric effectSemiconductorThermal conductivityEpitaxyOptoelectronicsWaferThermoelectric materialsFigure of meritChemical vapor depositionCondensed matter physicsNanotechnologyComposite materialLayer (electronics)ThermodynamicsPhysicsPhotonic and Optical DevicesNanowire Synthesis and ApplicationsAdvanced Thermoelectric Materials and Devices