Electrode Catalyst Research Articles

Going from Pt to PGM-free Catalysts: Effects of Ink Compositions on PEM Water Electrolysis.

The commercialisation of PEM water electrolysis is still hindered by the necessity of using noble metals that are rare, expensive and therefore unsustainable. To replace the benchmark HER catalyst Pt with more abundant materials, promising non-noble catalysts need to be identified and optimal electrode preparation and electrolysis conditions need to be transferred between catalyst materials to reveal their full potential under industrially relevant conditions. This study investigates the optimal ink composition for spray-coating the cathode regarding the effects on electrode structure, performance and catalyst layer composition. The ratio of catalyst to binder and carbon support was varied as well as the specific carbon material and the resulting electrodes were analysed via polarisation curves, electrochemical impedance spectroscopy, X-ray photo-electron spectroscopy and scanning electron microscopy for three different catalysts. These results show that ink compositions with a catalyst : carbon : binder ratio of 3:1:1 using Carbon Vulcan give the highest performance. Interestingly, resulting trends concerning electrochemical behaviour and electrode structure observed with different characterisation techniques can be transferred between Pt catalysts and non-noble transition metal chalcogenide materials. Boosting the performance via ink optimisation is much more pronounced for the non-noble catalysts, narrowing the gap to competing with noble standard Pt materials.

Electrode Selection and Catalyst Evaluation in Hydrogen Production from Alkaline Water Electrolysis: A Review

Generating hydrogen, through alkaline water electrolysis shows promise as an energy source. This review delves into the significance of choosing the electrodes and evaluating catalysts to enhance the efficiency and performance of hydrogen production. It summarizes the activation energy and losses linked to reactions in alkaline electrolysis emphasizing the necessity for electrode materials and catalysts. The review also touches upon challenges such as electricity consumption and platinum group metal based electro catalysts proposing various electrode materials and catalysts with superior activity and selectivity for hydrogen production. Additionally, it discusses electrolysis cell designs that facilitate separating by-products from hydrogen gas. The study reveals that with low over potentials of 70, 318, and 361 mV at 10, 500, and 1000 mA cm−2, respectively, NiOx/NF exhibits strong alkaline hydrogen evolution activity, resulting in great performance in alkaline HER. Moreover, it outlines advancements in alkaline water electrolysis technology focusing on enhanced efficiency and reduced operating costs associated with electricity consumption. Overall this review underscores the role of selecting electrodes and evaluating catalysts in optimizing hydrogen production from alkaline water electrolysis.

Multimodal Measurement Evaluation on the Surface of Electrode Catalysts in Fuel Cells

Multimodal Measurement Evaluation on the Surface of Electrode Catalysts in Fuel Cells

Quasi-solid-state monolithic DSSCs with optimized spacer layers and composite electrolytes for better efficiency and stability

In this study, high-performance quasi-solid-state monolithic dye-sensitized solar cells (QS-M-DSSCs) were designed using an optimized spacer layer architecture to enhance electrolyte transport and improve cell performance. Spacer layers, made from a combination of zirconium oxide (ZrO2) and titanium dioxide (TiO2), were precisely tuned to reduce mass-transport limitations. A 5.2 μm thick ZrO2/TiO2 layer provided good light reflectance and incident photon-to-current conversion efficiency compared to double layers of either material alone. Electrochemical impedance spectroscopy analysis of the m-DSSCs revealed that this architecture (photoelectrode TiO2 layer/ZrO2/TiO2 spacer layer/counter electrode catalyst layer) significantly increased recombination resistance, leading to an improvement in open-circuit voltage. As a result, acetonitrile iodide liquid-DSSCs using N719 dye achieved a high power conversion efficiency (PCE) of 8.45 %, surpassing cells with alternative spacer designs. For fully printable QS-M-DSSCs, printable gel electrolytes (PGEs) composed of polyethylene oxide and polymethyl methacrylate in 3-methoxypropionitrile (MPN) were employed. A 5 wt% PEO/PMMA composition demonstrated fast and efficient penetration of the PGEs through spacer layers. Moreover, incorporation of 4 wt% TiO2 nanoparticles into PGEs further enhanced their electrochemical properties, achieving a PCE (7.31 %) higher than cells with liquid electrolytes (6.72 %). QS-M-DSSCs demonstrated greater stability than liquid-state DSSCs.

N, S double-doped GQDs intercalated nanoflower-like MoS2 as an efficient counter electrode catalyst for DSSCs

N, S double-doped GQDs intercalated nanoflower-like MoS2 as an efficient counter electrode catalyst for DSSCs

Economical iron-based catalyst electrode for highly stable catalytic industrial-scale overall seawater splitting

The development of economical and stable catalyst electrodes for industrial-scale seawater splitting is one of the current challenges in hydrogen production. The economical transition metals possess high electrical conductivity and offer the potential for designing electrodes with high intrinsic activity through appropriate modifications, thus holding promising applications in industrial contexts. Herein, a durable and economical self-supported bifunctional electrode (Fe@Ni) with high efficiency and large area is successfully constructed by one step in-situ deposition of iron on the porous structure of nickel foam (NF) via mild (298 K) electroplating method. Transition metals like iron and nickel offer high electrical conductivity and can be properly modified to achieve electrodes with high intrinsic activity. Due to the in-situ growth of cost-effective iron on the NF surface, the electrode surface morphology and electronic structure are reconstructed, which significantly improves the electrochemical activity surface area and electron transfer capability of the electrode. The hydrogen/oxygen evolution reaction (HER/OER) in simulated seawater (1 M KOH + 0.5 M NaCl) require only 129 mV and 323 mV overpotentials to achieve a current density of 100 mA cm−2. Overall seawater splitting (OWS) achieves 10 mA cm−2 at a low voltage of 1.49 V and with a faradaic efficiency of nearly 100%. More importantly, the bifunctional electrodes remain stable at industrial-level current density (1.0 A cm−2) for more than 50 days. More attractively, this work realizes the universal construction of large-area electrode for multiple metals (e.g., Fe, Cu, Al, etc.) with mild and simple process, which provides a new strategy for the current research of energy and materials.

Effect of CO2 and HClO4 Concentrations on CO2 Reduction Reaction Intermediates at Pt Polycrystalline Electrode

Introduction To achieve carbon neutrality, it is necessary to apply practical CO2 reduction and effective utilization technologies. Recently, there has been an expectation for the electrochemical reduction of CO2 (CO2 Reduction Reaction: CO2RR) using electricity derived from renewable energy. CO2RR with low overvoltage using a polymer electrolyte membrane is an actively researched next-generation technology. It is important to improve Faraday efficiency and analyze CO2RR mechanisms. Cu electrode catalysts are commonly used for CO2RR due to their high Faraday efficiency. However, a challenge remains in reducing the overvoltage of CO2RR to the level of hydrogen generation in normal PEM water electrolysis. Although Pt electrode catalysts have a significantly lower Faraday efficiency for CO2RR than Cu electrode catalysts, they have been reported to have low overvoltage1. Recent research has shown that the presence of water in the supplied CO2 and the alloy composition enhances Faraday efficiency2,3. To reduce CO2RR overvoltage, this study utilized a Pt electrode. Successful CO2RR requires the electrode catalyst surface to have coexisting surface-adsorbed hydrogen (Had) and CO2RR intermediate (COad). This study investigates the effect of electrolyte pH (perchloric acid concentration) and CO2 concentration on the COad and Had, utilizing a Pt polycrystalline electrode. Experimental Electrochemical measurements were carried out using a three-electrode cell. The counter electrode was a Pt mesh, and the reference electrode was a reversible hydrogen electrode (RHE). The working electrode was a φ3 mm Pt polycrystalline disk electrode that was mirror-polished with a 0.05 μm alumina suspension. Cyclic voltammetry (CV) measurements were performed with a sweep range of 0.05-1.0 V vs. RHE and a sweep rate of 50 mV/s or 10 mV/s. The results of the CV measurements are presented after IR correction. To evaluate CO2RR, the concentration of HClO4 was adjusted to 0.01-0.5 M as the electrolyte. The CO2 concentration was varied from 0-100 vol% and bubbled for 30 minutes before the CV measurements. For the electrochemical evaluation of CO2RR, the initial potential was kept at 0.05-0.4 V for 5 minutes before the CV measurements, and then the CV measurement was performed. Results and Discussion 1. CO2RR potential in HClO4 electrolyte saturated with 100% CO2 Figure 2 shows the results of CV measurements performed after holding the initial potentials at 0.05-0.4 V for 5 minutes before starting the CV measurements. The bubbling CO2 concentration during the measurements was 100%, and the HClO4 concentration was 0.1 M. In comparison to the CV peaks observed in the N2 atmosphere, peaks where the CO2RR reduction intermediate (COad) are reoxidized are observed at 0.6-0.7 V in the 100% CO2 atmosphere. The charge of these COad peaks remain constant at low initial holding potentials. However, it decreases significantly as the initial holding potential approaches 0.4 V. Under the measurement conditions of 100% CO2 atmosphere and 0.1 M HClO4 concentration, it can be seen that CO2 is reduced on the Pt electrode at a potential positive of 0 V vs. RHE because the COad peaks are seen between 0.05-0.3 V of the initial holding potentials. 2. Dependence of COad peak on bubbling CO2 concentration CV measurements were performed by changing the CO2 concentration bubbled in 0.1 M HClO4. Figure 3 shows the results of CV measurements at an initial potential hold of 0.05 V, where the CO2 concentration was changed from 0% to 100%. In the Hupd region, the amount of charge decreases in the CO2 atmosphere because CO2 is already surface-adsorbed as COad at 0.05 V, and the decrease is larger as the CO2 concentration increases. It is evident that the peaks of COad increase as the concentration of CO2 increases. Additionally, when the CO2 concentration is low, the peaks of COad are divided into at least two peaks, indicating the generation of COad with different adsorption structures during CO2RR. As the CO2 concentration increases, the peaks of COad appearing on the low potential side also increase. Additionally, the ratio of COad with different adsorption structures might change depending on the CO2 concentration bubbled. Acknowledgements This work was supported by JSPS KAKENHI Grant Number JP23K13835 and TEPCO Memorial Foundation.

Accelerated Stress Testing (AST) Protocol Development for Heavy-Duty Fuel Cells

: Polymer electrolyte membrane fuel cells (PEMFCs) are promising for heavy duty applications due to their unique scalability in terms of both power and energy [1], and the U.S. Department of Energy (DOE) established the Million Mile Fuel Cell Truck (M2FCT) consortium in 2020 to advance fuel cell truck R&D[2, 3]. The 2025 end-of-life (EOL) target of M2FCT is to achieve 2.5 kW/gPGM at 0.7 V after 25, 000 hour-equivalent accelerated durability test. Several novel materials have been developed and integrated into membrane electrode assemblies (MEA) and catalysts that meet the EOL target after 90,000 potential cycles in H2/N2 have been reported. However, these reports do not imply that the M2FCT 2025 target has been met since development of the durability protocol and lifetime prediction models for heavy-duty fuel cells are ongoing efforts. The tentative heavy-duty MEA accelerated stress test (AST) protocol consists of H2/Air potential cycling under elevated temperature (90 °C) [4], which the consortium is still actively refining based on the feedback received from the AST Working Group (ASTWG).In this talk, we will systematically summarize the results from the 500-hour H2/Air testing MEA AST, together with various characterization results from microscopy and X-ray analysis, as well as nondispersive infrared to measure support carbon corrosion and fluoride emission rates to measure membrane degradation. With better understanding of the degradation for each component under different testing conditions, we will illustrate the effect of RH (30%, 50%, 90%, and 100%) on the degradation rates of the membrane and catalyst and explain the rationale behind the proposed MEA AST protocol. The degradation rates from the MEA AST protocol were fit into lifetime prediction models and acceleration factors were calculated based on different RHs and cathode catalyst loadings. Refinement of the protocol based on feedback received will also be briefly introduced. Acknowledgment: We acknowledge the financial support for this work from the U.S. DOE) Hydrogen and Fuel Cell Technologies Office (HFTO) through the M2FCT consortium, technology managers Greg Kleen and Dimitrios Papageoropoulos.

Highly Active Raney-Nickel Electrodes Based on 3D Pin Structures for Use in High Temperature Alkaline Electrolysis

The efficiency of alkaline electrolysers can be improved in a multitude of ways from overall system design to optimal operation conditions. One possibility is to increase the operating temperature which usually is 80 °C for industrial electrolysers. Increasing the temperature is a straightforward way to increase system efficiency significantly but leads to escalating corrosion problems due to the high concentration of KOH and the presence of oxygen (dissolved and gas phase) in the anolyte.In this work we have developed highly active electrodes for the use at 120 °C. The electrodes are based on engineered 3D pin structures that were coated with Raney-Nickel. Since the interplay between electrode structure and catalyst layer are crucial for electrode performance in alkaline electrolysis a selection of nickel pin structures based on nickel mesh with differences in pillar as well as hole shape and size were investigated to find a optimal configuration. The aluminum for the formation of leachable NiAl-phases was applied by rolling Aluminum foil of varying thickness onto the pin structures. A following heat treatment and leaching resulted in a layer of Raney-Nickel on the substrates. The general performance at standard operating conditions was investigated as well as the behavior at 120 °C in 40 wt% KOH. The obtained electrodes showed excellent performance at a current density of 500 mA/cm² with overvoltages below 110 mV as cathodes and below 300 mV as anodes. During these tests and an additional testing campaign, the corrosion resistance of the Ni substrate and specially developed alloys under anodic conditions were evaluated. Figure 1

X-Ray Scattering Characterization of Pt and PtCo Catalyst Inks and Electrodes for PEFC Cathodes

The composition and processing of the catalyst-ionomer ink used to fabricate electrochemical energy conversion device electrodes can impact the final electrode microstructure and performance. Parameters influencing the microstructure and performance are, for example, solvent ratio, ink processing method and time, ionomer chemistry, and carbon morphology/porosity. Polymer electrolyte fuel cell (PEFC) cathodes are typically prepared by first dispersing a catalyst powder, comprised of platinum or platinum alloy nanoparticles supported on carbon blacks, with ionomer in solvents, followed by extensive mixing using a variety of methods. The electrode properties are controlled by the interactions of the ionomer with the catalyst particles and the support in the catalyst-ionomer ink, by the effect of ink solvent composition on those interactions, and by the ink mixing and coating procedures. This presentation will describe the in-situ/ex-situ ultra-small angle X-ray scattering (USAXS) combined with SAXS studies of the evolution of the cathode catalyst layer to determine the effect of ink processing variables and ink composition on the ink properties, especially on the carbon agglomerate break-up for efficient coating of catalyst layers while optimizing fuel cell performance and durability. The effect of ink formulation is examined for Pt-supported Vulcan carbon (Pt/Vu) and Pt and PtCo-supported on high surface area carbon (Pt and PtCo/HSC) with different ionomers. The results provide the fundamental understanding enabling improved membrane-electrode assembly (MEA) performance and durability. Moreover, the results of the evolution of the catalyst layer during the ink drying process as a function of solvent removal rate and solvent identity will be discussed. Acknowledgments This work was supported by the U.S. Department of Energy, Energy Efficiency and Renewable Energy, Hydrogen and Fuel Cell Technologies Office under the M2FCT Consortium. This work was authored in Argonne National Laboratory, a U.S. Department of Energy (DOE) Office of Science laboratory operated for DOE by UChicago Argonne, LLC under contract no. DE-AC02-06CH11357. This research used the resources of the Advanced Photon Source (APS), a U.S. Department of Energy (DOE) Office of Science User Facility operated for the DOE Office of Science by Argonne National Laboratory under Contract No. DE-AC02-06CH11357.

(Invited) Degradation Mechanisms, Diagnostics, and Mitigation in Proton Exchange Membrane Water Electrolyzers

Hydrogen has unique advantages as an energy carrier, with a high energy density and abilities for long term storage and conversion between electricity and chemical bonds. Although hydrogen currently has a significant role in transportation and agriculture, its use in energy consumption overall has been limited. With decreasing electricity prices, electrolysis cost reductions can be achieved and allow for an opportunity for greater use. While load-following renewable power sources can reduce feedstock cost, further cost reductions can be achieved by decreasing stack and system cost.1 Proton exchange membrane (PEM) water electrolyzers rely on platinum group metal (PGM) catalysts due to the high anode potentials and low pH of proton conducting systems.2 While iridium (Ir) abundance is a potential concern for the ubiquitous deployment of PEM water electrolyzers,3,4 thrifting Ir while improving performance and durability is critical for reaching hydrogen cost targets.Efforts are needed and underway to understand electrolyzer degradation and develop accelerated stress tests when accounting for lower PGM loadings and hydrogen cost reduction targets.5 In this presentation, studies correlating operational and shutdown strategies to performance losses, identifying degradation mechanisms, and evaluating their impact on electrolyzer lifetime will be discussed. Depending on catalyst/interfacial properties and operational parameters, processes including catalyst/transport layer migration, and catalyst reordering, segregation, and oxidation have been observed and linked between ex situ characterization and in situ diagnostics. Through these studies, shutdown processes and catalyst redox transitions have generally been found to increase loss rates; varying catalyst types and morphologies, however, can also present significant integration challenges particularly when focusing on low PGM loading and durability testing.Mitigation options have further been explored that can address degradation processes, including catalyst development and electrode design strategies. Within catalysis, commercial screenings and development efforts have both modified materials properties and catalyst/ionomer/pore distribution throughout the catalyst layer. In some cases, electrode design efforts have also led to altered site utilization and changed the extent to which operational stressors utilize the entire catalyst layer, impacting performance losses over time. Catalysis of the oxygen evolution reaction by Ir will be discussed as it relates to current status in the tradeoff between electrolyzer cost, performance, and lifetime; particular challenges in PEM durability and accelerated stress test development will be also discussed as well as it relates to other low temperature electrolysis technologies.[1] B. Pivovar, N. Rustagi and S. Satyapal, The Electrochemical Society Interface, 27, 47 (2018).[2] K. Ayers, N. Danilovic, R. Ouimet, M. Carmo, B. Pivovar and M. Bornstein, Annual Review of Chemical and Biomolecular Engineering, 10, 219 (2019).[3] Cortney Mittelsteadt, Esben Sorensen, and Qingying Jia, Ir Strangelove, or How to Learn to Stop Worrying and Love the PEM Water Electrolysis Energy Fuels 37, 12558 (2023).[4] Mark Clapp, Christopher M. Zalitis, Margery Ryan, Perspectives on current and future iridium demand and iridium oxide catalysts for PEM water electrolysis, Catalysis Today 420, 114140 (2023).[5] Pivovar, B. S.; Boardman, R., H2NEW: Hydrogen (H2) from Next-generation Electrolyzers of Water, 2023.[6] Electron microscopy was performed at the Center for Nanophase Materials Sciences, which is a DOE Office of Science User Facility.[7] X-ray spectroscopy and scattering performed at the Advanced Photon Source at Argonne National Laboratory, a DOE Office of Science User Facility.

Effect of Post-Heat Treatment of Catalysts Under Various Gas Conditions on the Microstructure of Catalysts Ink and Electrode for PEMFC

Polymer electrolyte membrane fuel cells (PEMFCs) directly convert the chemical energy of fuel into electrical energy, producing electricity through a high-efficiency, ecofriendly energy conversion device. While PEMFCs are commercialized now, enhancing their competitiveness compared to other energy sources is critical and requires an understanding of the microstructure of the membrane-electrode assembly. Typically, fuel cell electrodes are manufactured by coating an electrolyte membrane with catalyst inks composed of electrode catalyst, ionomer, and solvent or additives. To maximize the performance of fuel cells, the proper distribution of catalysts and ionomers within the electrode is essential, and the microstructure within the electrode is determined by the interactions between the carbon support and platinum surface, as well as the dispersion of catalysts and ionomers in the solvent. Thus, the internal microstructure of the catalyst ink, determined by the interactions among its constituents, ultimately defines the final electrode microstructure, affecting the performance and durability of the fuel cell. This study aims to analyze the effects of post-heat treatment of catalyst in various gas atmospheres, including NH3 gas, on the surface characteristics and to examine the changes in interactions between the catalysts and ionomers within the catalyst ink following surface modification. Additionally, this research seeks to elucidate the correlation between the properties of the catalyst ink and the characteristics of the electrode produced by drying the ink. To this end, the physical properties of the thermally modified catalysts were analyzed, and the resulting catalyst ink was also manufactured and examined. The physical and rheological properties of the catalyst ink were assessed using a dispersing analyzer and rheometer to understand the interactions between the catalysts and ionomers. Furthermore, the coatability of the catalyst ink and the structural characteristics of the electrode were investigated. Figure 1

Next Generation Cathode Catalyst Layer Design with High Oxygen Permeable Ionomer – Benefits, Challenges, and Prospects for Heavy Duty Fuel Cell Applications

Proton Exchange Membrane Fuel Cell (PEMFC) has a growing demand to power zero emission fuel cell applications. Ballard is the fuel cell industry leader, developing the next generation core technology to fulfill such demand and giving continuous efforts on cost reduction. Key requirements in fuel cell market applications include high power density and long-life operation, while maintaining high efficiencies and reducing costs. This places a high demand on improving catalyst performance and electrode layer transport, which can be sustained over the duration of the product lifetime. To reduce fuel cell membrane electrode assembly (MEA) cost, the push for high performance catalyst layers (CLs) with low platinum (Pt) loadings results in new challenges for the cathode material selection and electrode design. The increased oxygen transport resistance that occurs at lower catalyst loadings with reduced available catalyst electrochemical active surface area (ECSA), causes two very closely related challenges: 1) greater performance losses at high current density increases the difficulty to achieve the power requirements for the heavy duty market, and 2) the loss of catalyst ECSA via platinum dissolution over time puts additional demands on the design to achieve the end of life (EOL) performance requirement. Therefore, a combination of material solution, design choice and processing parameters are the key to optimize next generation cathode design for fuel cell applications1.One material solution to achieve high performance while reducing catalyst loadings is the development of high oxygen permeable ionomer (HOPI) that mitigates oxygen transport limitations at the Pt surface. Chemours has developed a HOPI with a bulky, sterically rigid monomer group in the ionomer backbone, which disrupts the packing density, improving oxygen permeability on the catalyst surface2. One of the key challenges of HOPI integration and the scale-able fabrication of the catalyst layer is high crack density of CL due to the rigid nature of the ionomer. Ballard has integrated HOPI in the cathode CL overcoming scale-able fabrication challenges through appropriate process parameter selection and evaluated CL performance. The use of accelerated testing and modeling approach developed by numerous product iteration, has been applied for lifetime estimation for HOPI technology introduction. In this talk, we will discuss details about benefit of High Oxygen Permeable Ionomer (HOPI) in next generation cathode CL design.Recently, key requirements in heavy-duty market applications are placing more importance on high efficiency rather than high power density to reduce fuel cost rather catalyst cost. Reaching the target lifetime, catalyst overloading to 0.45 mg/cm2 total Pt in anode and cathode, and 44% active membrane area oversizing are suggested3. Therefore, to achieve high efficiency target, high catalyst activity is more desired. Interestingly, HOPI also showed high specific activity due to the mitigation of catalyst poisoning by sulfonate anion groups4. We will also discuss the catalyst layer design prospect with HOPI for such transition on heavy duty market application.Acknowledgement: US Department of Energy (DOE) funded heavy duty MEA development project (DE-EE0008822).References M. Dutta, A. Young, V. Colbow, J. Bellerive and S. Knights 2020 Examining Catalyst Layer Design Strategies for Improved Fuel Cell Performance and Durability. ECS PRiME 2020S. Litster et al. 2020 Durable High-Power Density Fuel Cell Cathodes for Heavy-Duty Vehicle. DOE AMR 2020K. Ahluwalia and X. Wang 2024 Performance and Durability of Hybrid Fuel Cell Systems for Class-8 Long Haul Trucks. J. Electrochem. Soc. 171 034507R. Jinnouchi, K. Kudo and K. Kodama 2021 The role of oxygen-permeable ionomer for polymer electrolyte fuel cells. Nat Commun 12, 4956.

Graphitic Engineered Carbon Supports for Fuel Cell and Electrolyzer Catalysts: Significance and Characterization Methodology

Interconnected mesoporous carbons are an integral support material for many fuel cell and electrolyzer electrode catalysts because of their conductivity, their structural tunability, and the abundance of carbon precursors. The structure and morphology of the carbon support have significant impacts on electrocatalyst performance and durability, and improvements to the synthesis and characterization of carbon supports will ultimately advance sustainable fuel cell and electrolyzer technologies towards widespread adoption. One essential aspect of the carbon structure is its “degree of graphitization,” or the proportion of sp2-hybridized crystalline graphite structures that comprise the solid carbon. Graphitization of solid carbon supports can improve their stability against oxidation and corrosion, ultimately improving the durability and thus catalyst lifetime of fuel cell and electrolyzer devices; as such, it is essential to have detailed methodologies, both quantitative and qualitative, to describe the “degree of graphitization” of carbon supports for performance optimization. Here, we discuss techniques for characterizing the degree of graphitization of solid carbons such as powder X-ray diffractometry (PXRD), Raman spectroscopy, and wide-angle X-ray scattering (WAXS), and apply these techniques to a new class of carbon materials developed by Pajarito Powder known as the Engineered Catalyst Support (ECS). ECS materials are mesoporous carbons with tunable mesopore structures and graphitization levels, allowing these techniques to be demonstrated across a related series of carbon materials. From this analysis, a recommended methodology is given for characterization of graphitic carbon supports in the context of fuel cell and electrolyzer technologies.

Regulating Assembly of Porous Electrode Catalyst Layers

Polymer-electrolyte fuel cells (PEFCs) demonstrate remarkable potential in replacing non-renewable energy resources in paving the way for a sustainable future. PEFCs have fairly high efficiencies and energy densities, making them feasible for applications such as transportation and energy storage. The most expensive units of the PEFCs are the catalyst layers, traditionally composed of platinum interspersed on a carbon support with a perfluorosulfonic acid (PFSA) which stabilizes the ink dispersions as well acts as a binder for the dried catalyst layers. Despite the great importance of optimizing the composition of the catalyst layer to improve the practicality of PEFCs, predicting the performance of the final structure of the fuel cell remains a challenge.In this talk, we outline an approach to predict key properties of the catalyst layers such as the porosity and particle sizes that compose it through mathematical modeling of the ink properties. We discuss a kinetics-based algorithm based on interacting particles that simultaneously solves for the size distributions of the particles and the pH of the ink, a parameter that can be used for verification. The results of the aggregation formulation will be fed into calculations to determine fundamental properties of the catalyst layer, such as porosity through a void fraction calculation. To verify the accuracy of this approach, we will compare against experimental data for varying concentrations and solvents. The insights gained from these considerations will enable efficient design of future catalyst layers.

Study on Catalyst and Binder Degradation Analysis during Electrode Degradation Using EIS in PEMFC

Research is underway to reduce the cost of PEMFCs by decreasing the loading amount of Pt catalyst, which necessitates research on catalyst structures and binders to compensate for the resulting decrease in performance and durability. Recent studies have focused on improving performance using binders such as high oxygen permeation ionomer (HOPI), but research on the durability of such binders is lacking. The primary challenge in studying binder durability lies in the difficulty of binder degradation analysis. Since the binder in the catalyst layer exists in small quantities within the catalyst layer, and degradation is difficult to distinguish from membrane degradation, it is crucial to develop analysis methods to identify binder degradation. Distribution relaxation time (DRT) analysis is a method that utilizes Electrochemical Impedance Spectroscopy (EIS) to analyze resistance in detail by representing it as distribution relaxation time peaks. By using DRT analysis, the resistance in EIS can be subdivided into ORR charge transfer resistance, oxygen transfer resistance, and proton transfer resistance and changes in the ion transfer resistance of the catalyst layer can be analyzed in situ to observe binder degradation. In this study, we aim to analyze the degradation of catalyst and binder ionomer during electrode degradation using EIS in situ. In addition, we compare the electrochemical analysis results and post-analysis results with the EIS analysis results to examine the suitability for EIS analysis. Electrode degradation was carried out using the DOE catalyst degradation protocol. Characterization during electrode degradation included I-V, EIS, mass activity, CV, LSV, while post-degradation analysis involved AFM, XRD, XRF analysis to analyze electrode catalyst and binder degradation. As catalyst degradation progressed, the cell's performance decreased, leading to increased charge transfer resistance (CTR), decreased electrochemical surface area (ECSA), and decreased mass activity. Catalyst degradation was observed through changes in ORR charge transfer resistance in DRT analysis, while binder degradation was confirmed through changes in proton transfer resistance in DRT results and Warburg-like response impedance. The results obtained from the postmortem of degraded MEAs matched well with the results obtained from DRT analysis.

Study on the Distribution of Platinum within Polymer Membrane during MEA Degradation in PEMFC

The Pt/C added to the PEMFC polymer membrane serves as a gas barrier, facilitating the generation of water through the hydrogen and oxygen combustion reactions on the Pt surface within the membrane. As water is produced, Pt acts as an antioxidant, humidifying the membrane and preventing radical generation, thus enhancing performance and durability. Pt needs to be closely spaced between particles to act as a radical scavenger, and it has been reported that under different operating and degradation conditions, the size and distribution of Pt within the membrane vary. Therefore, this experiment aimed to observe the movement and distribution changes of Pt/C within the membrane during accelerated degradation.In this experiment, Pt/C was added to the cathode ionomer layer to manufacture a reinforced membrane with a thickness of 15 μm. The MEA was produced by hot pressing Pt/C electrodes onto the reinforced membrane, with a Pt loading of 0.4 mg/cm2. After assembling the MEA into a cell, chemical durability evaluations of the electrode catalyst, catalyst support, and membrane were conducted. The cross-sections of the MEA before and after degradation were analyzed using SEM and TEM to confirm the distribution of Pt within the membrane.After chemical degradation of the polymer membrane, Pt/C within the membrane remained stationary, but dissolved/deposited Pt within the electrode layer migrated into the membrane, indicating a closer proximity between Pt/C and Pt. During catalyst and catalyst support degradation, movement of Pt/C within the membrane and changes in its distribution were observed.

Intermediate-Temperature Steam Electrolysis Using Phosphate-Based Thin Film Electrolytes

Hydrogen has been regarded as a key energy medium toward the realization of a carbon-neutral society. Currently, hydrogen is mostly derived from fossil fuel without capturing CO2, and does not contribute to carbon neutrality at all. Hydrogen production by water electrolysis powered by renewable electricity is attracting attention as an effective method for "green hydrogen" synthesis that does not emit CO2 in hydrogen production and utilization processes. As a water electrolysis device, we are working on solid-state electrolytic cells with a phosphate-based electrolyte operative at intermediate temperatures from ca. 100 to 300⁰C. This system offers excellent mass transfer characteristics of water (steam) in the electrode catalyst layer and superior electrode reaction kinetics due to an elevated temperature. In addition, it is applicable to electrochemical reduction of N2 and CO2 to NH3 [1] and hydrocarbons [2], respectively.Several studies using phosphate-based electrolytic cells reported steam electrolysis in the intermediate temperature range [3, 4]. So far, thick disk-type electrolyte and composites with polymers have been employed in steam electrolysis to maintain ionic conductivity and stability under high water vapor pressures, which resulted in high applied voltage and large ohmic loss. Therefore, we aimed to develop a highly efficient steam electrolytic cell at intermediate temperature and to reduce the effective resistance of the electrolyte by developing thin film electrolyte comprising of CsH5(PO4)2/SiP2O7, which exhibits high proton conductivity in the temperature range of 100 to 300°C. Thin film of the electrolyte was synthesized on a porous substrate, and the conductivity and stability of the electrolyte have been investigated. Steam electrolysis cell was fabricated using developed thin film electrolyte, and electrochemical performance of the cell was evaluated in steam electrolysis at intermediate temperatures.[1] Y. Yuan, S. Tada, R. Kikuchi, Mater. Adv., 2, 793 (2021).[2] N. Fujiwara, S. Tada, R. Kikuchi, iScience, 25, 105381 (2022)[3] N. Fujiwara, H. Nagase, S. Tada, R. Kikuchi, ChemSusChem, 14, 417 (2021)[4] P. Bretzler, E. Christensen, R.W. Berg, N.J. Bjerrum, Ionics, 28, 3421 (2022)

Influence of Ionic and Electronic Transport Properties on Ammonia Electrochemical Synthesis in Protonic Ceramic Fuel Cells

Energy carriers play an important role in chemical energy storage and transport technology for effective hydrogen utilization. Ammonia is a carbon-free fuel and a promising energy carrier in terms of high energy density and easy liquefaction. Electrochemical synthesis provides an efficient method, and protonic ceramic fuel cells (PCFCs) can be applied to ammonia production (N2 + 3H2O → 2NH3 + 1.5O2). We reported that Fe-based electrode catalysts with a proton-conducting solid electrolyte improved the ammonia formation rate by the electrochemical promotion of catalysis (EPOC) (1-3). Ionic and electronic transports in PCFCs can affect the ammonia formation reaction. In this study, we investigate the correlation between the electrochemical synthesis of ammonia and the transport properties of proton, oxide ion, and hole in the PCFCs to clarify the ammonia formation reaction.BaCe0.9Y0.1O3−δ (BCY10) electrolyte-supported cells were used for all experiments. A Fe cathode was deposited as the ammonia-forming electrode. For hydrogen pumping mode, Pt was used as the anode, while for water electrolysis mode, an electrode based on BaCo0.4Fe0.4Zr0.1Y0.1O3−δ (BCFZY) was used instead due to its triple-conducting properties (4). Electrochemical testing was conducted at 600 °C in a double-chamber reactor with the cathodic atmosphere fixed as dry 50% H2/N2. The ammonia produced bubbled into a dilute sulfuric acid solution and was quantified using liquid chromatography.With all cells, both the ammonia formation rates and current densities were shown to increase with applied voltage (Fig.1a). Under the dry H2 condition in the anode, the ammonia formation rate was shown to exhibit a strong dependence on the applied voltage, reaching 10−8 mol s−1 cm−2. Meanwhile, the ammonia formation rates were comparatively lower for hydrated conditions, i.e., wet H2 and wet air with 3%H2O. On the contrary, the current density was found to be lowest for dry H2 and highest for wet air, with a six-fold difference between the two conditions.The Nernst–Planck–Poisson (NPP) model was used to investigate the defect transport across the electrolyte and elucidate the experimental results. The NPP model was discretized and numerically calculated by improving our previous work (5). However, due to the unavailability of required thermodynamic and transport parameters for BCY10, a set of parameters reported for BaZr0.8Y0.2O3−δ (BZY20) was used instead (6). The fluxes of protons, oxygen vacancies, and holes were calculated at 600 °C with an applied voltage of 1 V under varying atmospheres (Fig. 1b). The cathodic atmosphere was fixed as dry 50% H2/N2, while three anodic atmospheres were considered, dry H2, wet H2, and wet air, considering the experimental conditions in this study. It was observed that under wet H2 conditions, proton flux significantly dominated the defect transport, showing an increase with rising voltage. In contrast, both hole and oxygen vacancy fluxes remained relatively insignificant compared to the proton flux regardless of applied voltage. However, under dry conditions, the oxygen vacancy flux became notable in relation to the total current and increased with higher voltages. Furthermore, higher current densities were observed under wet H2 compared to those under dry H2, indicating that total current might not be the most important factor in ammonia production. The NPP-model predictions imply that a higher oxygen vacancy flux toward the cathode could promote ammonia formation as well as proton flux. Under wet air, the proton transport number considerably decreases on the anode side due to the formation of holes. Even though the current density is significantly high, most of it consists of leakage current, as holes are the dominant charge carriers. Acknowledgments This work was supported by JSPS KAKENHI Grant Numbers JP21H04938. References F. Kosaka, T. Nakamura, A. Oikawa, J. Otomo, ACS Sustainable Chem. Eng., 5(11), 10439-10446 (2017).C.-I. Li, H. Matsuo, J. Otomo, Sustainable Energy & Fuels, 5, 188-198 (2021).M. Okazaki, J. Otomo, ACS Omega, 8 (43), 40299-40308 (2023).C. Duan, J. Tong, M. Shang, S. Nikodemski, M. Sanders, S. Ricote, A. Almansoori, R. O’Hayre. Science, 349 (6254), 1321–1326 (2015).J. A. Ortiz Corrales, H. Matsuo, J. Otomo, ECS Trans., 103 (1) 1763-1777 (2021).H. Zhu, S. Ricote, C. Duan, R. P. O’Hayre, D. S. Tsvetkov, and R. J. Kee, J. Electrochem. Soc., 165(9), F581–F588 (2018). Figure 1

(Invited) Organic Catalysis Promotor for Accelerating Oxygen Evolution Reaction Toward Advanced Water Electrolysis

As the concerns about energy and environmental issues rapidly increase, the requirements for developing renewable energy sources are highly demanded to achieve the carbon-neutrality by 2050. Among the suggested strategies for carbon neutrality, green hydrogen production via water electrolysis is treated as a promising breakthrough to alternate the currently used fossil fuel-based energy production since it utilizes clean and eco-friendly resources of water and electricity. However, there still remains a limitation of which mostly used noble metal-based catalyst materials such as iridium, and platinum result in severe carbon dioxide emission during production and recycling processes in addition to the extremely high cost and scarcity. Therefore, it is mandatory to minimize the noble metal contents in catalyst electrodes to ultimately reach carbon neutrality. Diverse approaches have been suggested to reduce the amount of noble metal contents such as developing non-noble metal catalysts and single-atom catalysts as well as designing electrode architecture for low loading on the support materials. Nonetheless, limited catalytic performances or increased process cost from suggested strategies still hinders the development of large-scale water electrolyzer. Herein, we suggest a novel concept of organic catalysis promotor as a strategy for minimizing noble metal contents in catalysts. Organic catalysis promotor as an additive in an electrolyte can enhance the hydrogen production efficiency with the spontaneous chemical interaction with the intermediate state of a catalyst during water electrolysis reaction, which can further result in reducing the required amount of noble metals for green hydrogen production. We developed the model organic catalysis promotor for oxygen evolution reaction in alkaline water electrolysis, and it successfully reduced overpotential of 70 mV at a current density of 100 mA cm-2 with only adding a slight amount of 1 mM organic catalysis promotor in KOH electrolyte. This catalysis promoting capability could be maintained even over a week, and the possibilities of further expansion of organic catalysis promotor material group and general applicability to representative oxygen evolution reaction catalysts were also proved. This novel concept of organic catalysis promotor has a great potential to be further expanded toward hydrogen evolution reaction promotion and acidic water electrolyzer. Furthermore, it can suggest a new breakthrough for the development of large-scale water electrolyzer with minimizing the noble metal contents in a sustainable and economical way.