Modeling of molecular photocells: application to two-level photovoltaic system with electron-hole interaction

Tahereh Nematiaram; Petrutza  Anghel-Vasilescu; Asghar  Asgari; Matthias  Ernzerhof; Didier  Mayou

doi:10.1063/1.4963335

Modeling of molecular photocells: application to two-level photovoltaic system with electron-hole interaction

Tahereh Nematiaram, Petrutza Anghel-Vasilescu, Asghar Asgari, Matthias Ernzerhof, Didier Mayou

Pure And Applied Chemistry

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Abstract

We present a novel simple model to describe molecular photocells where the energy conversion process takes place by a single molecular donor-acceptor complex attached to electrodes. By applying quantum scattering theory, an open quantum system method, the coherent molecular photocell is described by a wave function. We analyze photon absorption, energy conversion, and quantum yield of a molecular photocell by considering the effects of electron-hole interaction and non-radiative recombination. We model the exciton creation, dissociation, and subsequent effects on quantum yield in the energy domain. We find that depending on the photocell structure, the electron-hole interaction can normally decrease or abnormally increase the cell efficiency. The proposed model helps to understand the mechanisms of molecular photocells, and it can be used to optimize their yield

Original language	English
Article number	124116
Pages (from-to)	1-8
Number of pages	8
Journal	Journal of Chemical Physics
Volume	145
DOIs	https://doi.org/10.1063/1.4963335
Publication status	Published - 28 Sept 2016

Keywords

molecular photocells
photovoltaic system
electron-hole interaction
model
quantum scattering theory
coherent molecular photocell
cell efficiency

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10.1063/1.4963335

Nematiaram-etal-JCP2016-Modeling-molecular-photocells-application-two-level-photovoltaic-system-electron-hole-interactionAccepted author manuscript, 3.56 MB

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abstract = "We present a novel simple model to describe molecular photocells where the energy conversion process takes place by a single molecular donor-acceptor complex attached to electrodes. By applying quantum scattering theory, an open quantum system method, the coherent molecular photocell is described by a wave function. We analyze photon absorption, energy conversion, and quantum yield of a molecular photocell by considering the effects of electron-hole interaction and non-radiative recombination. We model the exciton creation, dissociation, and subsequent effects on quantum yield in the energy domain. We find that depending on the photocell structure, the electron-hole interaction can normally decrease or abnormally increase the cell efficiency. The proposed model helps to understand the mechanisms of molecular photocells, and it can be used to optimize their yield",

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AU - Nematiaram, Tahereh

AU - Anghel-Vasilescu, Petrutza

AU - Asgari, Asghar

AU - Ernzerhof, Matthias

AU - Mayou, Didier

PY - 2016/9/28

Y1 - 2016/9/28

N2 - We present a novel simple model to describe molecular photocells where the energy conversion process takes place by a single molecular donor-acceptor complex attached to electrodes. By applying quantum scattering theory, an open quantum system method, the coherent molecular photocell is described by a wave function. We analyze photon absorption, energy conversion, and quantum yield of a molecular photocell by considering the effects of electron-hole interaction and non-radiative recombination. We model the exciton creation, dissociation, and subsequent effects on quantum yield in the energy domain. We find that depending on the photocell structure, the electron-hole interaction can normally decrease or abnormally increase the cell efficiency. The proposed model helps to understand the mechanisms of molecular photocells, and it can be used to optimize their yield

AB - We present a novel simple model to describe molecular photocells where the energy conversion process takes place by a single molecular donor-acceptor complex attached to electrodes. By applying quantum scattering theory, an open quantum system method, the coherent molecular photocell is described by a wave function. We analyze photon absorption, energy conversion, and quantum yield of a molecular photocell by considering the effects of electron-hole interaction and non-radiative recombination. We model the exciton creation, dissociation, and subsequent effects on quantum yield in the energy domain. We find that depending on the photocell structure, the electron-hole interaction can normally decrease or abnormally increase the cell efficiency. The proposed model helps to understand the mechanisms of molecular photocells, and it can be used to optimize their yield

KW - molecular photocells

KW - photovoltaic system

KW - electron-hole interaction

KW - model

KW - quantum scattering theory

KW - coherent molecular photocell

KW - cell efficiency

U2 - 10.1063/1.4963335

DO - 10.1063/1.4963335

M3 - Article

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JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

M1 - 124116

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Modeling of molecular photocells: application to two-level photovoltaic system with electron-hole interaction

Abstract

Keywords

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