A study of quantum well solar cell structures with bound-to-continuum transitions for reduced carrier recombination | Zendy

G. Jolley | Zendy; L. Faraone | Zendy; Lan Fu | Zendy; Hao Lu | Zendy; Hark Hoe Tan | Zendy; C. Jagadish | Zendy

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A study of quantum well solar cell structures with bound-to-continuum transitions for reduced carrier recombination

Author(s) -

G. Jolley,

L. Faraone,

Lan Fu,

Hao Lu,

Hark Hoe Tan,

C. Jagadish

Publication year - 2013

Publication title -

applied physics letters

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 1.182

H-Index - 442

eISSN - 1077-3118

pISSN - 0003-6951

DOI - 10.1063/1.4807506

Subject(s) - quantum well , solar cell , bound state , wave function , electron , trapping , recombination , condensed matter physics , quasi fermi level , electronic band structure , atomic physics , quantum , physics , conduction band , chemistry , molecular physics , quantum mechanics , ecology , laser , biochemistry , gene , biology

A bound-to-continuum quantum well solar cell structure is proposed, and the band structure and absorption spectra are analyzed by the use of an eight band k·p model. The structure is based on quantum wells that only support bound states for the valence band. The absence of bound conduction band states has a number of potential advantages, including a reduction of electron trapping and, therefore, a reduction of quantum well induced photocarrier recombination due to reduced spatial overlap of the electron and hole wavefunctions.

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