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Physics-Based Modeling and Experimental Study of Si-Doped InAs/GaAs Quantum Dot Solar Cells
Physics-Based Modeling and Experimental Study of Si-Doped InAs/GaAs Quantum Dot Solar Cells
by Wu, Jiang , Khalili, A. , Cédola, A. P. , Cappelluti, F. , Kim, D. , Liu, H. , Tibaldi, A. , Tang, M.
in Applied physics / Charge transfer / Computer simulation / Doping / Efficiency / Gallium arsenide / Indium arsenides / Mathematical models / Open circuit voltage / Photovoltaic cells / Photovoltaic conversion / Quantum dots / Solar cells
2018
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Physics-Based Modeling and Experimental Study of Si-Doped InAs/GaAs Quantum Dot Solar Cells
by Wu, Jiang , Khalili, A. , Cédola, A. P. , Cappelluti, F. , Kim, D. , Liu, H. , Tibaldi, A. , Tang, M.
in Applied physics / Charge transfer / Computer simulation / Doping / Efficiency / Gallium arsenide / Indium arsenides / Mathematical models / Open circuit voltage / Photovoltaic cells / Photovoltaic conversion / Quantum dots / Solar cells
2018
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Physics-Based Modeling and Experimental Study of Si-Doped InAs/GaAs Quantum Dot Solar Cells
Physics-Based Modeling and Experimental Study of Si-Doped InAs/GaAs Quantum Dot Solar Cells
by Wu, Jiang , Khalili, A. , Cédola, A. P. , Cappelluti, F. , Kim, D. , Liu, H. , Tibaldi, A. , Tang, M.
in Applied physics / Charge transfer / Computer simulation / Doping / Efficiency / Gallium arsenide / Indium arsenides / Mathematical models / Open circuit voltage / Photovoltaic cells / Photovoltaic conversion / Quantum dots / Solar cells
2018

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Physics-Based Modeling and Experimental Study of Si-Doped InAs/GaAs Quantum Dot Solar Cells
Physics-Based Modeling and Experimental Study of Si-Doped InAs/GaAs Quantum Dot Solar Cells
Journal Article

Physics-Based Modeling and Experimental Study of Si-Doped InAs/GaAs Quantum Dot Solar Cells

Wu, Jiang,
Khalili, A.,
Cédola, A. P.,
Cappelluti, F.,
Kim, D.,
Liu, H.,
Tibaldi, A.,
Tang, M.
2018
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Overview
This paper presents an experimental and theoretical study on the impact of doping and recombination mechanisms on quantum dot solar cells based on the InAs/GaAs system. Numerical simulations are built on a hybrid approach that includes the quantum features of the charge transfer processes between the nanostructured material and the bulk host material in a classical transport model of the macroscopic continuum. This allows gaining a detailed understanding of the several physical mechanisms affecting the photovoltaic conversion efficiency and provides a quantitatively accurate picture of real devices at a reasonable computational cost. Experimental results demonstrate that QD doping provides a remarkable increase of the solar cell open-circuit voltage, which is explained by the numerical simulations as the result of reduced recombination loss through quantum dots and defects.
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Publisher
Hindawi Publishing Corporation,Hindawi,John Wiley & Sons, Inc,Wiley
Subject

Applied physics

/ Charge transfer

/ Computer simulation

/ Doping

/ Efficiency

/ Gallium arsenide

/ Indium arsenides

/ Mathematical models

/ Open circuit voltage

/ Photovoltaic cells

/ Photovoltaic conversion

/ Quantum dots

/ Solar cells

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