Engineering Temperature‐Dependent Carrier Concentration in Bulk Composite Materials via Temperature‐Dependent Fermi Level Offset

Abstract Precise control of carrier concentration in both bulk and thin‐film materials is crucial for many solid‐state devices, including photovoltaic cells, superconductors, and high mobility transistors. For applications that span a wide temperature range (thermoelectric power generation being a p...

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Bibliographic Details
Published in:Advanced energy materials 2017-09, Vol.8 (3)
Main Authors: Hui, Si, Gao, Wenpei, Lu, Xu, Panda, Anurag, Bailey, Trevor P., Page, Alexander A., Forrest, Stephen R., Morelli, Donald T., Pan, Xiaoqing, Pipe, Kevin P., Uher, Ctirad
Format: Article
Language:English
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Summary:Abstract Precise control of carrier concentration in both bulk and thin‐film materials is crucial for many solid‐state devices, including photovoltaic cells, superconductors, and high mobility transistors. For applications that span a wide temperature range (thermoelectric power generation being a prime example) the optimal carrier concentration varies as a function of temperature. This work presents a modified modulation doping method to engineer the temperature dependence of the carrier concentration by incorporating a nanosize secondary phase that controls the temperature‐dependent doping in the bulk matrix. This study demonstrates this technique by de‐doping the heavily defect‐doped degenerate semiconductor GeTe, thereby enhancing its average power factor by 100% at low temperatures, with no deterioration at high temperatures. This can be a general method to improve the average thermoelectric performance of many other materials.
ISSN:1614-6832
1614-6840