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Asymptotic and numerical prediction of current-voltage curves for an organic bilayer solar cell under varying illumination and comparison to the Shockley equivalent circuit

Asymptotic and numerical prediction of current-voltage curves for an organic bilayer solar cell under varying illumination and comparison to the Shockley equivalent circuit
Asymptotic and numerical prediction of current-voltage curves for an organic bilayer solar cell under varying illumination and comparison to the Shockley equivalent circuit
In this study, a drift-diffusion model is used to derive the current-voltage curves of an organic bilayer solar cell consisting of slabs of electron acceptor and electron donor materials sandwiched together between current collectors. A simplified version of the standard drift-diffusion equations is employed in which minority carrier densities are neglected. This is justified by the large disparities in electron affinity and ionisation potential between the two materials. The resulting equations are solved (via both asymptotic and numerical techniques) in conjunction with (i) Ohmic boundary conditions on the contacts and (ii) an internal boundary condition, imposed on the interface between the two materials, that accounts for charge pair generation (resulting from the dissociation of excitons) and charge pair recombination. Current-voltage curves are calculated from the solution to this model as a function of the strength of the solar charge generation. In the physically relevant power generating regime, it is shown that these current-voltage curves are well-approximated by a Shockley equivalent circuit model. Furthermore, since our drift-diffusion model is predictive, it can be used to directly calculate equivalent circuit parameters from the material parameters of the device.
carrier density, electron affinity, equivalent circuits, excitons, ionisation potential, organic compounds, solar cells
0021-8979
1-15
Foster, Jamie
6b1c0d1d-d594-4495-963f-573f2f0d1d19
Kirkpatrick, James
a0928102-efc4-4725-972e-5961a5b543c1
Richardson, Giles
3fd8e08f-e615-42bb-a1ff-3346c5847b91
Foster, Jamie
6b1c0d1d-d594-4495-963f-573f2f0d1d19
Kirkpatrick, James
a0928102-efc4-4725-972e-5961a5b543c1
Richardson, Giles
3fd8e08f-e615-42bb-a1ff-3346c5847b91

Foster, Jamie, Kirkpatrick, James and Richardson, Giles (2013) Asymptotic and numerical prediction of current-voltage curves for an organic bilayer solar cell under varying illumination and comparison to the Shockley equivalent circuit. Journal of Applied Physics, 114 (10), 1-15. (doi:10.1063/1.4820567).

Record type: Article

Abstract

In this study, a drift-diffusion model is used to derive the current-voltage curves of an organic bilayer solar cell consisting of slabs of electron acceptor and electron donor materials sandwiched together between current collectors. A simplified version of the standard drift-diffusion equations is employed in which minority carrier densities are neglected. This is justified by the large disparities in electron affinity and ionisation potential between the two materials. The resulting equations are solved (via both asymptotic and numerical techniques) in conjunction with (i) Ohmic boundary conditions on the contacts and (ii) an internal boundary condition, imposed on the interface between the two materials, that accounts for charge pair generation (resulting from the dissociation of excitons) and charge pair recombination. Current-voltage curves are calculated from the solution to this model as a function of the strength of the solar charge generation. In the physically relevant power generating regime, it is shown that these current-voltage curves are well-approximated by a Shockley equivalent circuit model. Furthermore, since our drift-diffusion model is predictive, it can be used to directly calculate equivalent circuit parameters from the material parameters of the device.

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e-pub ahead of print date: 9 September 2013
Published date: 14 September 2013
Keywords: carrier density, electron affinity, equivalent circuits, excitons, ionisation potential, organic compounds, solar cells
Organisations: Applied Mathematics

Identifiers

Local EPrints ID: 356840
URI: http://eprints.soton.ac.uk/id/eprint/356840
DOI: doi:10.1063/1.4820567
ISSN: 0021-8979
PURE UUID: 2d3ceb5d-2a8c-45d8-a21e-00ac2f274042
ORCID for Giles Richardson: ORCID iD orcid.org/0000-0001-6225-8590

Catalogue record

Date deposited: 16 Sep 2013 08:49
Last modified: 15 Mar 2024 03:33

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Contributors

Author: Jamie Foster
Author: James Kirkpatrick
Author: Giles Richardson ORCID iD

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