Can slow-moving ions explain hysteresis in the current-voltage curves of perovskite solar cells?
Can slow-moving ions explain hysteresis in the current-voltage curves of perovskite solar cells?
The hypothesis that ion motion is responsible for anomalous hysteresis in the current-voltage curves of perovskite solar cells is investigated through a combination of electrical transport modelling and experimental measurements. In a combined computational and experimental study, good agreement is obtained between experiment and the results of a charge transport model covering mixed ionic-electronic conduction. Our model couples electrons, holes and defect mediated ion motion suggesting that slow moving ions are indeed the origin of the hysteresis. The magnitude of the ion diffusion coefficient required to match experiment and theory, ?10?12 cm2 s?1, depends on the cell, but is similar to that predicted by microscopic theory of vacancy mediated diffusion. The investigation is extended to preconditioning procedures which are known to substantially influence the hysteresis. The method developed for solving the stiff equations in the drift diffusion model is widely applicable to other double layer problems occurring in electrochemical applications such as the evolution of transmembrane potentials in living cells.
1476-1485
Richardson, Giles
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O'Kane, Simon
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Niemann, Ralf
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Peltola, Timo
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Foster, Jamie
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Cameron, Petra
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Walker, Alison
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12 February 2016
Richardson, Giles
3fd8e08f-e615-42bb-a1ff-3346c5847b91
O'Kane, Simon
e438f569-9deb-4da8-8bb3-685d4d15e376
Niemann, Ralf
cc8edfe3-ec2c-47ec-9a23-e498fd075b42
Peltola, Timo
0a695182-ac35-47c0-97d9-ffd0189eff4a
Foster, Jamie
6b1c0d1d-d594-4495-963f-573f2f0d1d19
Cameron, Petra
1436ac82-451c-4c15-8354-9f9625611949
Walker, Alison
0786a028-362b-432e-92e2-12ac0ae8f40f
Richardson, Giles, O'Kane, Simon, Niemann, Ralf, Peltola, Timo, Foster, Jamie, Cameron, Petra and Walker, Alison
(2016)
Can slow-moving ions explain hysteresis in the current-voltage curves of perovskite solar cells?
Energy & Environmental Science, 9 (4), .
(doi:10.1039/C5EE02740C).
Abstract
The hypothesis that ion motion is responsible for anomalous hysteresis in the current-voltage curves of perovskite solar cells is investigated through a combination of electrical transport modelling and experimental measurements. In a combined computational and experimental study, good agreement is obtained between experiment and the results of a charge transport model covering mixed ionic-electronic conduction. Our model couples electrons, holes and defect mediated ion motion suggesting that slow moving ions are indeed the origin of the hysteresis. The magnitude of the ion diffusion coefficient required to match experiment and theory, ?10?12 cm2 s?1, depends on the cell, but is similar to that predicted by microscopic theory of vacancy mediated diffusion. The investigation is extended to preconditioning procedures which are known to substantially influence the hysteresis. The method developed for solving the stiff equations in the drift diffusion model is widely applicable to other double layer problems occurring in electrochemical applications such as the evolution of transmembrane potentials in living cells.
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Accepted/In Press date: 12 February 2016
e-pub ahead of print date: 12 February 2016
Published date: 12 February 2016
Organisations:
Applied Mathematics
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Local EPrints ID: 387907
URI: http://eprints.soton.ac.uk/id/eprint/387907
ISSN: 1754-5692
PURE UUID: b1ddfebf-67c3-45a5-bca2-52de3e8b8e80
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Date deposited: 17 Feb 2016 11:43
Last modified: 15 Mar 2024 03:33
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Author:
Simon O'Kane
Author:
Ralf Niemann
Author:
Timo Peltola
Author:
Jamie Foster
Author:
Petra Cameron
Author:
Alison Walker
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