Measurement of the Protonic and Electronic Conductivities of PEM Water Electrolyzer Electrodes

Mandal, Manas; Moore, M. S.; Secanell, Marc

doi:10.1021/acsami.0c12111

Cited by 46 publications

(54 citation statements)

References 62 publications

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“…This results in a higher in‐plane and through‐plane resistivity compared to fuel cell catalyst layers employing carbon supported Pt. [ 13 ] Full realization of the importance of electronic conductivity, distinctly different from protonic conductivity, in influencing current distributions, reaction overpotentials, and overall PEMWE stack efficiency has only recently started to receive sufficient attention. [ 13–15 ] Efficiency losses are exacerbated as anode catalyst loading decreases and ionomer:catalyst ratios are shifted to improve protonic conductivity through the electrode.…”

Section: Introductionmentioning

confidence: 99%

“…[ 13 ] Full realization of the importance of electronic conductivity, distinctly different from protonic conductivity, in influencing current distributions, reaction overpotentials, and overall PEMWE stack efficiency has only recently started to receive sufficient attention. [ 13–15 ] Efficiency losses are exacerbated as anode catalyst loading decreases and ionomer:catalyst ratios are shifted to improve protonic conductivity through the electrode. [ 13–15 ] Current strategies to mitigate resistive losses in oxide‐based catalyst layers include: refining catalyst morphology to improve both utilization and inter‐particle contact and contact with the gas diffusion media, [ 6,15,16,21 ] inclusion of microporous layers to improve contact between the gas diffusion media and the catalyst layer, [ 5,15,17,18 ] addition of supporting materials to improve electrical contact and lower resistivity throughout the catalyst layer, [ 14,19,20 ] etc.…”

Section: Introductionmentioning

confidence: 99%

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Nanoporous Iridium Nanosheets for Polymer Electrolyte Membrane Electrolysis

Chatterjee

Peng

Intikhab

et al. 2021

Advanced Energy Materials

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The growth of the hydrogen economy is predicated on advancements in electrochemical energy technologies, with water electrolysis as a key component to the technological portfolio. Much of the focus on anode catalyst development for polymer electrolyte membrane water electrolyzers (PEMWE) is centered on activity as controlled by compositional and morphological impacts on reactant/intermediate/product adsorption. However, the effectiveness of this strategy is found to be limited upon integration of these materials into PEMWE membrane electrode assemblies (MEA). Regardless of catalyst activity, the combination of electrode inhomogeneity, ionomer integration, and high density of oxide–oxide interfaces yields significant performance losses associated with poor catalytic electrode conductivity. Here many of these limitations are addressed through the development of a unique catalyst morphology composed of nanoporous Ir nanosheets (npIrx‐NS) that exhibit high catalytic activity for the anodic oxygen evolution reaction and superior electrode electronic conductivity in comparison to a commercial IrO2 nanoparticle catalyst. The utility of the npIrx‐NS is demonstrated through incorporation into PEMWE MEAs where their performance exceeds that of commercial catalyst coated membranes at loadings as low as 0.06 mgIr cm−2 while exhibiting a negligible loss in performance following 50 000 accelerated stress test cycles.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Nanoporous Iridium Nanosheets for Polymer Electrolyte Membrane Electrolysis

Chatterjee

Peng

Intikhab

et al. 2021

Advanced Energy Materials

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show abstract

“…[ 16 , 17 , 18 ] This narrative is at odds with recent work showing that i) oxygen transport through the titanium PTL may be a crucial limiting factor contributing to performance decline, [ 19 , 20 ] ii) high performance at ultra‐low loadings without MPLs is possible, [ 5 ] iii) catalyst layer ionic resistance dominates over electronic resistance when ionomer volume fraction is higher than 20%. [ 21 ]…”

Section: Introductionmentioning

confidence: 99%

Insights into Interfacial and Bulk Transport Phenomena Affecting Proton Exchange Membrane Water Electrolyzer Performance at Ultra‐Low Iridium Loadings

et al. 2021

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Interfacial and bulk properties between the catalyst layer and the porous transport layer (PTL) restrict the iridium loading reduction for proton exchange membrane water electrolyzers (PEMWEs), by limiting their mass and charge transport. Using titanium fiber PTLs of varying thickness and porosity, the bulk and interface transport properties are investigated, correlating them to PEMWEs cell performance at ultra‐low Ir loadings of ≈0.05 mgIr cm−2. Electrochemical experiments, tomography, and modeling are combined to study the bulk and interfacial impacts of PTLs on PEMWE performance. It is found that the PEMWE performance is largely dependent on the PTL properties at ultra‐low Ir loadings; bulk structural properties are critical to determine the mass transport and Ohmic resistance of PEMWEs while the surface properties of PTLs are critical to govern the catalyst layer utilization and electrode kinetics. The PTL‐induced variation in kinetic and mass transport overpotential are on the order of ≈40 and 60 mV (at 80 A mgIr−1), respectively, while a nonnegligible 35 mV (at 3 A cm−2) difference in Ohmic overpotential. Thus at least 150 mV improvement in PEMWE performance can be achieved through PTL structural optimization without membrane thickness reduction or advent of new electrocatalysts.

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“…The leading hypothesis is titanium passivation in the presence of oxygen at the anode side. This insulating layer on the titanium surface increases the contact resistance [42][43][44]; this measurement increase should be further investigated to test this phenomenon [39,45,46], which was not realized in this study.…”

Section: Eis At 3000 Hmentioning

confidence: 80%

“…These bubbles are supposed to be flushed out during changes in potential, resulting in the observed recovery. Periodically reducing or stopping the input current could be used as a specific dynamic operation to improve the performance and durability of a PEM [13,46].…”

Section: Reversible Voltage Decreasementioning

confidence: 99%

Impact of Power Converter Current Ripple on the Degradation of PEM Electrolyzer Performances

et al. 2022

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In this study, an endurance test of 3000 h was conducted on four equivalent proton exchange membrane (PEM) electrolyzers to identify and quantify the impact of an electric ripple current on their durability. Three different typical power converter waveforms and frequencies were explored. Signals were added to the same direct current carrier and also tested for reference. Performance comparison based on polarization curves and electrochemical impedance spectroscopy (EIS) analysis revealed that the ripple current favors degradation. Triangular waveform and a frequency of 10 kHz were identified as the most degrading conditions, leading to a sharp increase in high-frequency resistance (HFR) and the emergence of mass transport limitations due to the enhanced degradation of titanium mesh. Moreover, reversible losses were observed and further explorations are needed to decorrelate them from our observations.

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Measurement of the Protonic and Electronic Conductivities of PEM Water Electrolyzer Electrodes

Cited by 46 publications

References 62 publications

Nanoporous Iridium Nanosheets for Polymer Electrolyte Membrane Electrolysis

Nanoporous Iridium Nanosheets for Polymer Electrolyte Membrane Electrolysis

Insights into Interfacial and Bulk Transport Phenomena Affecting Proton Exchange Membrane Water Electrolyzer Performance at Ultra‐Low Iridium Loadings

Impact of Power Converter Current Ripple on the Degradation of PEM Electrolyzer Performances

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