Improving the stability, selectivity, and cell voltage of a bipolar membrane zero-gap electrolyzer for low-loss CO2 reduction
Improving the stability, selectivity, and cell voltage of a bipolar membrane zero-gap electrolyzer for low-loss CO2 reduction
Electrolyzers for CO2 reduction containing bipolar membranes (BPM) are promising due to low loss of CO2 as carbonates and low product crossover, but improvements in product selectivity, stability, and cell voltage are required. In particular, direct contact with the acidic cation exchange layer leads to high levels of H2 evolution with many common cathode catalysts. Here, Co phthalocyanine (CoPc) is reported as a suitable catalyst for a zero-gap BPM device, reaching 53% Faradaic efficiency to CO at 100 mA cm−2 using only pure water and CO2 as the input feeds. It is also shown that the cell voltage can be lowered by constructing a customized BPM using TiO2 water dissociation catalyst, however this is at the cost of decreased selectivity. Switching the pure-water anolyte to KOH improved both the cell voltage and CO selectivity (62% at 200 mA cm−2), but cation crossover could cause complications. The results demonstrate viable strategies for improving a BPM CO2 electrolyzer toward practical-scale CO2-to-chemicals conversion.
bipolar membrane, CO reduction, molecular catalyst, water dissociation, zero-gap electrolyzer
Siritanaratkul, Bhavin
9d5f809b-e4af-48fb-83e8-a5dbc8bdd899
Sharma, Preetam K.
acf2aca4-1c65-4c06-9f00-5f6eec40ac6e
Yu, Eileen H.
28e47863-4b50-4821-b80b-71fb5a2edef2
Cowan, Alexander J.
f115591e-a2e8-4810-ae4a-5ac540fb1485
25 May 2023
Siritanaratkul, Bhavin
9d5f809b-e4af-48fb-83e8-a5dbc8bdd899
Sharma, Preetam K.
acf2aca4-1c65-4c06-9f00-5f6eec40ac6e
Yu, Eileen H.
28e47863-4b50-4821-b80b-71fb5a2edef2
Cowan, Alexander J.
f115591e-a2e8-4810-ae4a-5ac540fb1485
Siritanaratkul, Bhavin, Sharma, Preetam K., Yu, Eileen H. and Cowan, Alexander J.
(2023)
Improving the stability, selectivity, and cell voltage of a bipolar membrane zero-gap electrolyzer for low-loss CO2 reduction.
Advanced Materials Interfaces, 10 (15), [2300203].
(doi:10.1002/admi.202300203).
Abstract
Electrolyzers for CO2 reduction containing bipolar membranes (BPM) are promising due to low loss of CO2 as carbonates and low product crossover, but improvements in product selectivity, stability, and cell voltage are required. In particular, direct contact with the acidic cation exchange layer leads to high levels of H2 evolution with many common cathode catalysts. Here, Co phthalocyanine (CoPc) is reported as a suitable catalyst for a zero-gap BPM device, reaching 53% Faradaic efficiency to CO at 100 mA cm−2 using only pure water and CO2 as the input feeds. It is also shown that the cell voltage can be lowered by constructing a customized BPM using TiO2 water dissociation catalyst, however this is at the cost of decreased selectivity. Switching the pure-water anolyte to KOH improved both the cell voltage and CO selectivity (62% at 200 mA cm−2), but cation crossover could cause complications. The results demonstrate viable strategies for improving a BPM CO2 electrolyzer toward practical-scale CO2-to-chemicals conversion.
Text
Adv Materials Inter - 2023 - Siritanaratkul - Improving the Stability Selectivity and Cell Voltage of a Bipolar Membrane
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Published date: 25 May 2023
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© 2023 The Authors. Advanced Materials Interfaces published by Wiley-VCH GmbH.
Keywords:
bipolar membrane, CO reduction, molecular catalyst, water dissociation, zero-gap electrolyzer
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Local EPrints ID: 499015
URI: http://eprints.soton.ac.uk/id/eprint/499015
PURE UUID: f0b86924-c0fa-4518-bab3-07e54e2fff46
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Date deposited: 06 Mar 2025 18:02
Last modified: 22 Aug 2025 02:45
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Author:
Bhavin Siritanaratkul
Author:
Preetam K. Sharma
Author:
Eileen H. Yu
Author:
Alexander J. Cowan
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