Quantum two-level model for excitonic solar cells

Tahereh Nematiaram; Didier  Mayou

doi:10.5772/intechopen.74996

Quantum two-level model for excitonic solar cells

Tahereh Nematiaram, Didier Mayou

Pure And Applied Chemistry

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Abstract

While improving the performance of excitonic solar cells (XSCs) has been a central effort of the scientific community for many years, theoretical approaches facilitating the understanding of electron-hole interaction, recombination and electron-phonon coupling effects on the cell performance are still needed. We present a novel simple model which is based on the quantum scattering theory, in particular on the Lippmann-Schwinger equation; this minimizes the complexity of the problem while providing useful and non-trivial insight into the mechanism governing photocell operation. In this formalism, both exciton pair creation and dissociation are treated in the energy domain, and therefore there is access to detailed spectral information, which can be used as a framework to interpret the charge separation yield. Our analysis helps to optimize the charge separation process and the energy transfer in excitonic solar cells.

Original language	English
Title of host publication	Solar Panels and Photovoltaic Materials
Editors	Beddiaf Zaidi
Place of Publication	London
Chapter	3
Number of pages	18
DOIs	https://doi.org/10.5772/intechopen.74996
Publication status	Published - 11 Jul 2018

Keywords

quantum model
two-level system
electron hole interaction
electron photon coupling
charge separation field

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abstract = "While improving the performance of excitonic solar cells (XSCs) has been a central effort of the scientific community for many years, theoretical approaches facilitating the understanding of electron-hole interaction, recombination and electron-phonon coupling effects on the cell performance are still needed. We present a novel simple model which is based on the quantum scattering theory, in particular on the Lippmann-Schwinger equation; this minimizes the complexity of the problem while providing useful and non-trivial insight into the mechanism governing photocell operation. In this formalism, both exciton pair creation and dissociation are treated in the energy domain, and therefore there is access to detailed spectral information, which can be used as a framework to interpret the charge separation yield. Our analysis helps to optimize the charge separation process and the energy transfer in excitonic solar cells.",

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T1 - Quantum two-level model for excitonic solar cells

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AU - Mayou, Didier

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N2 - While improving the performance of excitonic solar cells (XSCs) has been a central effort of the scientific community for many years, theoretical approaches facilitating the understanding of electron-hole interaction, recombination and electron-phonon coupling effects on the cell performance are still needed. We present a novel simple model which is based on the quantum scattering theory, in particular on the Lippmann-Schwinger equation; this minimizes the complexity of the problem while providing useful and non-trivial insight into the mechanism governing photocell operation. In this formalism, both exciton pair creation and dissociation are treated in the energy domain, and therefore there is access to detailed spectral information, which can be used as a framework to interpret the charge separation yield. Our analysis helps to optimize the charge separation process and the energy transfer in excitonic solar cells.

AB - While improving the performance of excitonic solar cells (XSCs) has been a central effort of the scientific community for many years, theoretical approaches facilitating the understanding of electron-hole interaction, recombination and electron-phonon coupling effects on the cell performance are still needed. We present a novel simple model which is based on the quantum scattering theory, in particular on the Lippmann-Schwinger equation; this minimizes the complexity of the problem while providing useful and non-trivial insight into the mechanism governing photocell operation. In this formalism, both exciton pair creation and dissociation are treated in the energy domain, and therefore there is access to detailed spectral information, which can be used as a framework to interpret the charge separation yield. Our analysis helps to optimize the charge separation process and the energy transfer in excitonic solar cells.

KW - quantum model

KW - two-level system

KW - electron hole interaction

KW - electron photon coupling

KW - charge separation field

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DO - 10.5772/intechopen.74996

M3 - Chapter

SN - 9781789234343

SN - 9781789234350

BT - Solar Panels and Photovoltaic Materials

A2 - Zaidi, Beddiaf

CY - London

ER -

Quantum two-level model for excitonic solar cells

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