A mediated vanadium flow battery: lignin as redox-targeting active material in the vanadium catholyte
A mediated vanadium flow battery: lignin as redox-targeting active material in the vanadium catholyte
Vanadium Redox Flow Batteries (VRFB) are promising candidates for stationary energy storage but show certain drawbacks at low energy densities (<30 Wh L-1) and a narrow operating temperature range (15-40°C). The latter is mainly caused by the limited stability of the catholyte at elevated temperatures. Therefore, in this work we introduce a stability enhanced vanadium catholyte with redox mediating properties conferred by the highly abundant organic polymer lignin to achieve higher performance in temperature range for a penetration of the VRFB systems in thermal applications. By reducing the vanadium concentration to 0.9 M the catholyte’s stability is significantly improved so that a wider operational temperature window for the flow cell can be exploited. To compensate the loss in energy density lignin as a solid capacity booster is added to the positive reservoir. Herein, the feasibility of lignin in combination with multiwalled carbon nanotubes as solid charge storage material is investigated by cyclic voltammetry and charge/discharge cycles at temperatures from 10°C to 45°C. Volumetric capacities >28 Ah L-1 are achieved for the capacity-boosted VRFB with 0.9 M catholyte that are comparable with the conventional 1.8 M vanadium electrolyte. The use of an abundant renewable resource like lignin in the VRFB could not only increase cell performance but also attribute to lower the high operational costs and environmental impact of the battery.
energy storage, lignin, redox targeting,, vanadium, Lignin, Vanadium, Redox targeting, Energy storage
Berling, Sabrina
32b190e4-6513-41d1-9bb3-538a44c809bb
Rodríguez Hidalgo, José Manuel
0d01370a-e2e0-4e3c-a005-f64ee8db599c
Patil, Nagaraj
180b6dc7-1d6b-4756-82c6-ca267576d9f9
Garcia-Quismondo, Enrique
a69eb1b0-78ce-4edb-8448-f5b0f338448f
Palma, Jesus
b528a148-1036-405d-ad52-b8dd5e4224ff
Ponce De Leon Albarran, Carlos
508a312e-75ff-4bcb-9151-dacc424d755c
15 September 2023
Berling, Sabrina
32b190e4-6513-41d1-9bb3-538a44c809bb
Rodríguez Hidalgo, José Manuel
0d01370a-e2e0-4e3c-a005-f64ee8db599c
Patil, Nagaraj
180b6dc7-1d6b-4756-82c6-ca267576d9f9
Garcia-Quismondo, Enrique
a69eb1b0-78ce-4edb-8448-f5b0f338448f
Palma, Jesus
b528a148-1036-405d-ad52-b8dd5e4224ff
Ponce De Leon Albarran, Carlos
508a312e-75ff-4bcb-9151-dacc424d755c
Berling, Sabrina, Rodríguez Hidalgo, José Manuel, Patil, Nagaraj, Garcia-Quismondo, Enrique, Palma, Jesus and Ponce De Leon Albarran, Carlos
(2023)
A mediated vanadium flow battery: lignin as redox-targeting active material in the vanadium catholyte.
Journal of Energy Storage, 68, [107620].
(doi:10.1016/j.est.2023.107620).
Abstract
Vanadium Redox Flow Batteries (VRFB) are promising candidates for stationary energy storage but show certain drawbacks at low energy densities (<30 Wh L-1) and a narrow operating temperature range (15-40°C). The latter is mainly caused by the limited stability of the catholyte at elevated temperatures. Therefore, in this work we introduce a stability enhanced vanadium catholyte with redox mediating properties conferred by the highly abundant organic polymer lignin to achieve higher performance in temperature range for a penetration of the VRFB systems in thermal applications. By reducing the vanadium concentration to 0.9 M the catholyte’s stability is significantly improved so that a wider operational temperature window for the flow cell can be exploited. To compensate the loss in energy density lignin as a solid capacity booster is added to the positive reservoir. Herein, the feasibility of lignin in combination with multiwalled carbon nanotubes as solid charge storage material is investigated by cyclic voltammetry and charge/discharge cycles at temperatures from 10°C to 45°C. Volumetric capacities >28 Ah L-1 are achieved for the capacity-boosted VRFB with 0.9 M catholyte that are comparable with the conventional 1.8 M vanadium electrolyte. The use of an abundant renewable resource like lignin in the VRFB could not only increase cell performance but also attribute to lower the high operational costs and environmental impact of the battery.
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Accepted/In Press date: 2 May 2023
e-pub ahead of print date: 17 May 2023
Published date: 15 September 2023
Additional Information:
Funding Information:
The authors wish to thank the Spanish Ministry of Science and Innovation (MCIN/AEI/FEDER) for financial support through the GeoBATT project ( RTC-2017-5955-3 ) as well as the OMBAT project (Ref. PID2021- 124974OB-C21 ) and Dr. Rachel McKerracher from the University of Southampton for her assistance with the scanning electron microscopy measurements.
Publisher Copyright:
© 2023
Keywords:
energy storage, lignin, redox targeting,, vanadium, Lignin, Vanadium, Redox targeting, Energy storage
Identifiers
Local EPrints ID: 477416
URI: http://eprints.soton.ac.uk/id/eprint/477416
ISSN: 2352-152X
PURE UUID: 5a165639-e8a3-4e9e-a137-ce998f2da95c
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Date deposited: 06 Jun 2023 16:52
Last modified: 17 Mar 2024 03:01
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Contributors
Author:
Sabrina Berling
Author:
José Manuel Rodríguez Hidalgo
Author:
Nagaraj Patil
Author:
Enrique Garcia-Quismondo
Author:
Jesus Palma
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