Quantification of water transport in a CO electrolyzer
A sufficient supply of water at the catalyst layer is needed to mediate the CO 2 reduction reaction (CO 2 RR), yet too much water favours the competing hydrogen evolution reaction (HER) and lowers the efficiency of CO 2 electrolysis. It is therefore important to quantify water at the cathode, but CO...
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Published in | Energy & environmental science Vol. 13; no. 12; pp. 5126 - 5134 |
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Main Authors | , , , , , |
Format | Journal Article |
Published |
16.12.2020
|
Online Access | Get full text |
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Abstract | A sufficient supply of water at the catalyst layer is needed to mediate the CO
2
reduction reaction (CO
2
RR), yet too much water favours the competing hydrogen evolution reaction (HER) and lowers the efficiency of CO
2
electrolysis. It is therefore important to quantify water at the cathode, but CO
2
electrolyzers are typically enclosed systems where only the inputs and outputs can be readily measured. We report herein an analytical CO
2
RR electrolyzer with sensors in the cathode chamber to directly measure the relative humidity (RH) and temperature during electrolysis. These measurements enable the flow of water to be tracked inside the flow cell, and provide the boundary conditions necessary for a 3D model of mass transport and fluid flow in the cathode chamber. We developed a 3D model which showed that the molar fraction of water at the cathodic GDE/membrane interface,
x
H
2
O,mem
, is constant under a range of applied current densities (25-200 mA cm
−2
) and CO
2
flow rates (25-200 sccm), and does not change as a function of humidification of the CO
2
feed. The value of
x
H
2
O,mem
is held at parity because more water is drawn across the membrane (from the liquid-fed anode) when insufficient water is supplied to the cathode from the CO
2
feed. This result points to a higher flux of water across the membrane when using drier CO
2
feedstocks at higher flow rates and higher current densities. Consequently, undesirable anolyte crossover (which causes salt precipitation at the cathode) can be suppressed by maintaining a humidified CO
2
feed. This 3D model can be used for a range of operating conditions, materials, and flow fields to help with CO
2
RR electrolyzer design and optimization.
The distribution and flow of water in a CO
2
electrolyzer can be defined at variable operating conditions using a 3D model coupled with an analytical electrolyzer. |
---|---|
AbstractList | A sufficient supply of water at the catalyst layer is needed to mediate the CO
2
reduction reaction (CO
2
RR), yet too much water favours the competing hydrogen evolution reaction (HER) and lowers the efficiency of CO
2
electrolysis. It is therefore important to quantify water at the cathode, but CO
2
electrolyzers are typically enclosed systems where only the inputs and outputs can be readily measured. We report herein an analytical CO
2
RR electrolyzer with sensors in the cathode chamber to directly measure the relative humidity (RH) and temperature during electrolysis. These measurements enable the flow of water to be tracked inside the flow cell, and provide the boundary conditions necessary for a 3D model of mass transport and fluid flow in the cathode chamber. We developed a 3D model which showed that the molar fraction of water at the cathodic GDE/membrane interface,
x
H
2
O,mem
, is constant under a range of applied current densities (25-200 mA cm
−2
) and CO
2
flow rates (25-200 sccm), and does not change as a function of humidification of the CO
2
feed. The value of
x
H
2
O,mem
is held at parity because more water is drawn across the membrane (from the liquid-fed anode) when insufficient water is supplied to the cathode from the CO
2
feed. This result points to a higher flux of water across the membrane when using drier CO
2
feedstocks at higher flow rates and higher current densities. Consequently, undesirable anolyte crossover (which causes salt precipitation at the cathode) can be suppressed by maintaining a humidified CO
2
feed. This 3D model can be used for a range of operating conditions, materials, and flow fields to help with CO
2
RR electrolyzer design and optimization.
The distribution and flow of water in a CO
2
electrolyzer can be defined at variable operating conditions using a 3D model coupled with an analytical electrolyzer. |
Author | Mowbray, Benjamin A. W Habibzadeh, Faezeh Berlinguette, Curtis P Wheeler, Danika G Reyes, Angelica He, Jingfu |
AuthorAffiliation | Department of Chemistry Department of Chemical and Biological Engineering The University of British Columbia Stewart Blusson Quantum Matter Institute Canadian Institute for Advanced Research (CIFAR) |
AuthorAffiliation_xml | – name: Department of Chemistry – name: Canadian Institute for Advanced Research (CIFAR) – name: The University of British Columbia – name: Stewart Blusson Quantum Matter Institute – name: Department of Chemical and Biological Engineering |
Author_xml | – sequence: 1 givenname: Danika G surname: Wheeler fullname: Wheeler, Danika G – sequence: 2 givenname: Benjamin A. W surname: Mowbray fullname: Mowbray, Benjamin A. W – sequence: 3 givenname: Angelica surname: Reyes fullname: Reyes, Angelica – sequence: 4 givenname: Faezeh surname: Habibzadeh fullname: Habibzadeh, Faezeh – sequence: 5 givenname: Jingfu surname: He fullname: He, Jingfu – sequence: 6 givenname: Curtis P surname: Berlinguette fullname: Berlinguette, Curtis P |
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Notes | 10.1039/d0ee02219e Electronic supplementary information (ESI) available: Details on flow electrolyzer design and assembly, technical drawings showing the positioning, wiring, and calibration of RH & T sensors, model development and verification, boundary conditions, and supplementary figures referenced throughout this report (PDF). See DOI |
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Snippet | A sufficient supply of water at the catalyst layer is needed to mediate the CO
2
reduction reaction (CO
2
RR), yet too much water favours the competing... |
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Title | Quantification of water transport in a CO electrolyzer |
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