Thermoelectrical Field Effects in Low Dimensional Structure Solar Cells

Araujo; Barnham; Baruch; Bockelmann; Efros; Fardi; Henry; Herring; Hovel; Ioffe; Jean-Francois Guillemoles; Klimov; Koga; Lee; Li; Luque; Murdin; Nelson; Nelson; Parrott; Pauwels; Piotrowski; Ross; Seeger; Shockley; Stauber; Stefan Kettemann; Tsui; Urayama; Wuerfel

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Thermoelectrical Field Effects in Low Dimensional Structure Solar Cells

Authors: Araujo
Barnham
Baruch
Bockelmann
Efros
Fardi
Henry
Herring
Hovel
Ioffe
Jean-Francois Guillemoles
Klimov
Koga
Lee
Li
Luque
Murdin
Nelson
Nelson
Parrott
Pauwels
Piotrowski
Ross
Seeger
Shockley
Stauber
Stefan Kettemann
Tsui
Urayama
Wuerfel
Publication date: 1 January 2002
Publisher: 'Elsevier BV'
Doi

Abstract

Taking into account the temperature gradients in solar cells, it is shown that their efficiency can be increased beyond the Shockley-Queisser limit (J. Appl. Phys. 32 (1961) 510). The driving force for this gain is the temperature gradient between this region and its surroundings. A quantitative theory is given. Though the effect is found to be weak in conventional solar cells, it is argued that it can be substantially increased by proper choice of materials and design of the device. In particular, it is shown that the insertion of a quantum well can enhance the efficiency beyond one of the single gap cell, due to the presence of temperature jumps at the heterojunctions.Comment: Published in Special issue Physica E 14 (1-2) on Nanostructures in Photovoltaic

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