Trichome-like Carbon-Metal Fabrics Made of Carbon Microfibers, Carbon Nanotubes, and Fe-Based Nanoparticles as Electrodes for Regenerative Hydrogen/Vanadium Flow Cells

Barun Kumar Chakrabarti; Evangelos Kalamaras; Mengzheng Ouyang; Xinhua Liu; Guillaume Remy; Paul F. Wilson; Mark A. Williams; J. Rubio-Garcia; Vladimir Yufit; Gerard Bree; Yashar S. Hajimolana; Abhishek Singh; Farid Tariq; Chee Tong John Low; Billy Wu; Chandramohan George; Nigel Peter Brandon

doi:10.1021/acsanm.1c02195

Trichome-like Carbon-Metal Fabrics Made of Carbon Microfibers, Carbon Nanotubes, and Fe-Based Nanoparticles as Electrodes for Regenerative Hydrogen/Vanadium Flow Cells

Barun Kumar Chakrabarti^*, Evangelos Kalamaras, Mengzheng Ouyang, Xinhua Liu, Guillaume Remy, Paul F. Wilson, Mark A. Williams, J. Rubio-Garcia, Vladimir Yufit, Gerard Bree, Yashar S. Hajimolana, Abhishek Singh, Farid Tariq, Chee Tong John Low, Billy Wu, Chandramohan George, Nigel Peter Brandon

^*Corresponding author for this work

Thermal Engineering

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Abstract

Regenerative hydrogen/vanadium flow cells (RHVFCs) require electrode architectures combining electrochemical, catalytic, and mechanical properties across nano-, micro-, and milliscales. The use of current carbon-based electrodes can lead to poor electrolyte utilization, slow kinetics, and rapid electrode deterioration, resulting in suboptimal electrochemical performance and hindering RHVFC's commercial viability. To address this, we here demonstrate the application of trichome-like carbon-metal fabrics (CMFs) made of carbon microfibers, carbon nanotubes, and iron-based nanoparticles as both a catalytic layer and electrode in RHVFCs by evaluating their key figures of merit. CMFs in combination with commercial carbon cloth not only offer a high power density ∼645 mW cm-2 (∼0.82 V) but also excellent cycling performance at 150 mA cm-2, yielding nearly 100% energy efficiency and a high average discharge capacity of ∼23 Ah L-1 (∼90% electrolyte utilization). These electrochemical results together with electrode microstructural features assessed by X-ray tomography and projected cost analysis represent a step change in the design and development of tailored electrodes capable of withstanding RHVFC cycling conditions without compromising electrochemical performance.

Original language	English
Pages (from-to)	10754-10763
Number of pages	10
Journal	ACS Applied Nano Materials
Volume	4
Issue number	10
Early online date	8 Oct 2021
DOIs	https://doi.org/10.1021/acsanm.1c02195
Publication status	Published - 22 Oct 2021

Keywords

carbon nanotubes
carbonized microfiber
fabric electrodes
hydrogen
nanoparticles
redox flow battery
vanadium electrolyte
2023 OA procedure

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10.1021/acsanm.1c02195

acsanm.1c02195Final published version, 7.29 MBLicence: Taverne

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Chakrabarti, B. K., Kalamaras, E., Ouyang, M., Liu, X., Remy, G., Wilson, P. F., Williams, M. A., Rubio-Garcia, J., Yufit, V., Bree, G., Hajimolana, Y. S., Singh, A., Tariq, F., Low, C. T. J., Wu, B., George, C., & Brandon, N. P. (2021). Trichome-like Carbon-Metal Fabrics Made of Carbon Microfibers, Carbon Nanotubes, and Fe-Based Nanoparticles as Electrodes for Regenerative Hydrogen/Vanadium Flow Cells. ACS Applied Nano Materials, 4(10), 10754-10763. https://doi.org/10.1021/acsanm.1c02195

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title = "Trichome-like Carbon-Metal Fabrics Made of Carbon Microfibers, Carbon Nanotubes, and Fe-Based Nanoparticles as Electrodes for Regenerative Hydrogen/Vanadium Flow Cells",

abstract = "Regenerative hydrogen/vanadium flow cells (RHVFCs) require electrode architectures combining electrochemical, catalytic, and mechanical properties across nano-, micro-, and milliscales. The use of current carbon-based electrodes can lead to poor electrolyte utilization, slow kinetics, and rapid electrode deterioration, resulting in suboptimal electrochemical performance and hindering RHVFC's commercial viability. To address this, we here demonstrate the application of trichome-like carbon-metal fabrics (CMFs) made of carbon microfibers, carbon nanotubes, and iron-based nanoparticles as both a catalytic layer and electrode in RHVFCs by evaluating their key figures of merit. CMFs in combination with commercial carbon cloth not only offer a high power density ∼645 mW cm-2 (∼0.82 V) but also excellent cycling performance at 150 mA cm-2, yielding nearly 100% energy efficiency and a high average discharge capacity of ∼23 Ah L-1 (∼90% electrolyte utilization). These electrochemical results together with electrode microstructural features assessed by X-ray tomography and projected cost analysis represent a step change in the design and development of tailored electrodes capable of withstanding RHVFC cycling conditions without compromising electrochemical performance.",

keywords = "carbon nanotubes, carbonized microfiber, fabric electrodes, hydrogen, nanoparticles, redox flow battery, vanadium electrolyte, 2023 OA procedure",

author = "Chakrabarti, {Barun Kumar} and Evangelos Kalamaras and Mengzheng Ouyang and Xinhua Liu and Guillaume Remy and Wilson, {Paul F.} and Williams, {Mark A.} and J. Rubio-Garcia and Vladimir Yufit and Gerard Bree and Hajimolana, {Yashar S.} and Abhishek Singh and Farid Tariq and Low, {Chee Tong John} and Billy Wu and Chandramohan George and Brandon, {Nigel Peter}",

note = "Funding Information: This work received financial support from UKRI “Vanadium-Hydrogen flow battery for energy storage applications—a feasibility study” (EP/N508585/1), EPSRC ISCF Wave 1: 3D electrodes from 2D materials (EP/R023034/1) and Lab X-ray CT grant reference EP/T02593X/1 from EPSRC National Research Facility. Dr. Yuhua Xia is acknowledged for useful discussions. C.G. acknowledges funding from The Royal Society for an URF (UF160573). Publisher Copyright: {\textcopyright} 2021 American Chemical Society.",

year = "2021",

month = oct,

day = "22",

doi = "10.1021/acsanm.1c02195",

language = "English",

volume = "4",

pages = "10754--10763",

journal = "ACS Applied Nano Materials",

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Chakrabarti, BK, Kalamaras, E, Ouyang, M, Liu, X, Remy, G, Wilson, PF, Williams, MA, Rubio-Garcia, J, Yufit, V, Bree, G, Hajimolana, YS, Singh, A, Tariq, F, Low, CTJ, Wu, B, George, C & Brandon, NP 2021, 'Trichome-like Carbon-Metal Fabrics Made of Carbon Microfibers, Carbon Nanotubes, and Fe-Based Nanoparticles as Electrodes for Regenerative Hydrogen/Vanadium Flow Cells', ACS Applied Nano Materials, vol. 4, no. 10, pp. 10754-10763. https://doi.org/10.1021/acsanm.1c02195

Trichome-like Carbon-Metal Fabrics Made of Carbon Microfibers, Carbon Nanotubes, and Fe-Based Nanoparticles as Electrodes for Regenerative Hydrogen/Vanadium Flow Cells. / Chakrabarti, Barun Kumar; Kalamaras, Evangelos; Ouyang, Mengzheng et al.
In: ACS Applied Nano Materials, Vol. 4, No. 10, 22.10.2021, p. 10754-10763.

Research output: Contribution to journal › Article › Academic › peer-review

TY - JOUR

T1 - Trichome-like Carbon-Metal Fabrics Made of Carbon Microfibers, Carbon Nanotubes, and Fe-Based Nanoparticles as Electrodes for Regenerative Hydrogen/Vanadium Flow Cells

AU - Chakrabarti, Barun Kumar

AU - Kalamaras, Evangelos

AU - Ouyang, Mengzheng

AU - Liu, Xinhua

AU - Remy, Guillaume

AU - Wilson, Paul F.

AU - Williams, Mark A.

AU - Rubio-Garcia, J.

AU - Yufit, Vladimir

AU - Bree, Gerard

AU - Hajimolana, Yashar S.

AU - Singh, Abhishek

AU - Tariq, Farid

AU - Low, Chee Tong John

AU - Wu, Billy

AU - George, Chandramohan

AU - Brandon, Nigel Peter

N1 - Funding Information: This work received financial support from UKRI “Vanadium-Hydrogen flow battery for energy storage applications—a feasibility study” (EP/N508585/1), EPSRC ISCF Wave 1: 3D electrodes from 2D materials (EP/R023034/1) and Lab X-ray CT grant reference EP/T02593X/1 from EPSRC National Research Facility. Dr. Yuhua Xia is acknowledged for useful discussions. C.G. acknowledges funding from The Royal Society for an URF (UF160573). Publisher Copyright: © 2021 American Chemical Society.

PY - 2021/10/22

Y1 - 2021/10/22

N2 - Regenerative hydrogen/vanadium flow cells (RHVFCs) require electrode architectures combining electrochemical, catalytic, and mechanical properties across nano-, micro-, and milliscales. The use of current carbon-based electrodes can lead to poor electrolyte utilization, slow kinetics, and rapid electrode deterioration, resulting in suboptimal electrochemical performance and hindering RHVFC's commercial viability. To address this, we here demonstrate the application of trichome-like carbon-metal fabrics (CMFs) made of carbon microfibers, carbon nanotubes, and iron-based nanoparticles as both a catalytic layer and electrode in RHVFCs by evaluating their key figures of merit. CMFs in combination with commercial carbon cloth not only offer a high power density ∼645 mW cm-2 (∼0.82 V) but also excellent cycling performance at 150 mA cm-2, yielding nearly 100% energy efficiency and a high average discharge capacity of ∼23 Ah L-1 (∼90% electrolyte utilization). These electrochemical results together with electrode microstructural features assessed by X-ray tomography and projected cost analysis represent a step change in the design and development of tailored electrodes capable of withstanding RHVFC cycling conditions without compromising electrochemical performance.

AB - Regenerative hydrogen/vanadium flow cells (RHVFCs) require electrode architectures combining electrochemical, catalytic, and mechanical properties across nano-, micro-, and milliscales. The use of current carbon-based electrodes can lead to poor electrolyte utilization, slow kinetics, and rapid electrode deterioration, resulting in suboptimal electrochemical performance and hindering RHVFC's commercial viability. To address this, we here demonstrate the application of trichome-like carbon-metal fabrics (CMFs) made of carbon microfibers, carbon nanotubes, and iron-based nanoparticles as both a catalytic layer and electrode in RHVFCs by evaluating their key figures of merit. CMFs in combination with commercial carbon cloth not only offer a high power density ∼645 mW cm-2 (∼0.82 V) but also excellent cycling performance at 150 mA cm-2, yielding nearly 100% energy efficiency and a high average discharge capacity of ∼23 Ah L-1 (∼90% electrolyte utilization). These electrochemical results together with electrode microstructural features assessed by X-ray tomography and projected cost analysis represent a step change in the design and development of tailored electrodes capable of withstanding RHVFC cycling conditions without compromising electrochemical performance.

KW - carbon nanotubes

KW - carbonized microfiber

KW - fabric electrodes

KW - hydrogen

KW - nanoparticles

KW - redox flow battery

KW - vanadium electrolyte

KW - 2023 OA procedure

UR - http://www.scopus.com/inward/record.url?scp=85117751993&partnerID=8YFLogxK

U2 - 10.1021/acsanm.1c02195

DO - 10.1021/acsanm.1c02195

M3 - Article

AN - SCOPUS:85117751993

SN - 2574-0970

VL - 4

SP - 10754

EP - 10763

JO - ACS Applied Nano Materials

JF - ACS Applied Nano Materials

IS - 10

ER -

Trichome-like Carbon-Metal Fabrics Made of Carbon Microfibers, Carbon Nanotubes, and Fe-Based Nanoparticles as Electrodes for Regenerative Hydrogen/Vanadium Flow Cells

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