Radiation-grafted Anion-exchange Membranes Research Articles

(Invited) The Latest Developments in Radiation-Grafted Anion-Exchange Membranes

This invited lecture will discuss the latest developments in radiation-grafted anion-exchange membranes (RG-AEM) that are being developed for a wide range of electrochemical technologies including fuel cells, electrolysers, and reverse electrodialysis.This presentation will discuss the following key points:RG-AEMs can have very high conductivities and water diffusivities, however they generally have excessive water uptakes and degrees of swelling in water, as well as poor permselectivities when in contact with aqueous salt solutions.Crosslinking can reduce swelling and improve permselectivities, but this is at the expense of conductivity.The cationic headgroup chemistries can alter the water uptakes of the RG-AEMs, which can impact properties such as their alkali stability and permselectivity.Subtle changes in amination can lead to RG-AEMs with very different water contents and diffusivities.When fully hydrated, RG-AEMs in the alkali forms can have usefully high stabilities at temperatures above 60oC.RG-AEMs can be made with multiple chemical functionalities either via the co-grafting of more than one monomer or via amination using more than one amine reagent (see scheme below).Finally, the presentation will present some recent undergraduate project results that probe the homogeneity of grafting using a new titration technique. Figure 1

Radiation-grafted anion-exchange membranes: key features for enhanced water electrolysis

Tailored, radiation-induced grafted anion-exchange membranes (RIG-AEMs) are incorporated in anion-exchange membrane water electrolyzers. Fabrication parameters of the polymeric electrolyte directly impact the performance of electrochemical devices. The effect of radiation...

Covalent Crosslinking of High-Density Polyethylene Trimethylammonium-Based Radiation-Grafted Anion Exchange Membranes for Reduced Water Uptakes and Swelling

Anion exchange membranes (AEMs) are polymer membranes of varying thickness (10 - 50 µm) with covalently bound quaternary ammonium cations, which have been evaluated in fuel cells (AEMFCs) and green hydrogen electrolysis.1,2 Radiation-grafted AEMs made from high-density polyethylene (RG-HDPE) with ca. 30 microns hydrated thickness exhibit high hydroxide conductivities, promising mechanical stabilities, and high AEMFC performances.1,3 The enhanced water transport properties is hypothesized to be from nano and microscale level structural and morphological changes.3 Our best performing ultrathin RG-HDPE films exhibited excellent conductivity and AEMFC performance retention over the 400 h.3 However, the water uptake of RG-HDPE film is ca. 150%, hence, it is important to add a controlled amount of crosslinking.4-7 In previous studies of radiation-grafted membranes for use in reverse electrodialysis, crosslinking + amination was achieved by using a heated amination fabrication step involving a mixture of liquid, high boiling point mono-amines (such as N-methylpiperidine) and a crosslinking diamine (such as N,N,N',N'-tetramethyl-1,6-hexane diamine - TMHDA).8 However, a thermal method is not viable or safe when using the commonly supplied aqueous solutions of dissolved trimethylamine (TMA) gas. This presentation will discuss a variety of approaches, to target controlled TMHDA-crosslinking of TMA-based RG-AEMs, targeting reduced water uptakes and swelling with retention of ion conductivity (Figure 1). The most promising approach involved two steps with the initial amination of the poly(VBC)-grafted HDPE intermediate membranes using a sub-stoichiometric amount of TMHDA. Square wave voltammetry analysis of the solution recovered from amination step 1 confirmed complete reaction of the added TMHDA. In the second step, the membranes were then quickly [important] reacted with aqueous TMA to complete the amination process. TMA can displace TMHDA-based head-groups after long step 2 amination times, hence, we emphasize the use of short TMA amination times in the second step.

Influence of Headgroups in Ethylene-Tetrafluoroethylene-Based Radiation-Grafted Anion Exchange Membranes for CO2 Electrolysis.

The performance of zero-gap CO2 electrolysis (CO2E) is significantly influenced by the membrane's chemical structure and physical properties due to its effects on the local reaction environment and water/ion transport. Radiation-grafted anion-exchange membranes (RG-AEM) have demonstrated high ionic conductivity and durability, making them a promising alternative for CO2E. These membranes were fabricated using two different thicknesses of ethylene-tetrafluoroethylene polymer substrates (25 and 50 μm) and three different headgroup chemistries: benzyl-trimethylammonium, benzyl-N-methylpyrrolidinium, and benzyl-N-methylpiperidinium (MPIP). Our membrane characterization and testing in zero-gap cells over Ag electrocatalysts under commercially relevant conditions showed correlations between the water uptake, ionic conductivity, hydration, and cationic-head groups with the CO2E efficiency. The thinner 25 μm-based AEM with the MPIP-headgroup (ion-exchange capacities of 2.1 ± 0.1 mmol g-1) provided balanced in situ test characteristics with lower cell potentials, high CO selectivity, reduced liquid product crossover, and enhanced water management while maintaining stable operation compared to the commercial AEMs. The CO2 electrolyzer with an MPIP-AEM operated for over 200 h at 150 mA cm-2 with CO selectivities up to 80% and low cell potentials (around 3.1 V) while also demonstrating high conductivities and chemical stability during performance at elevated temperatures (above 60 °C).

Radiation-grafted anion-exchange membranes for CO2 electroreduction cells: an unexpected effect of using a lower excess of N-methylpiperidine in their fabrication

Radiation-grafted methylpiperidinium anion-exchange membranes fabricated using different amine excesses are spectroscopically similar but possess different nano-morphological and hydration responses.

Changes in permselectivity of radiation-grafted anion-exchange membranes with different cationic headgroup chemistries are primarily due to water content differences

For anion-exchange membranes, different cationic chemistries change the balance between permselectivity and conductivity, due to changes in water content.

(Invited) Radiation-Grafted Anion-Exchange Membranes for Reverse Electrodialysis (RED): The Effect of Changing Functional Groups on Key Properties

Radiation-grafted anion-exchange membranes (RG-AEM) are being developed at the University of Surrey in order to study a variety of chemistries and morphologies for use in a range of electrochemical applications. It is now clear that the ideal base films and grafted functional chemistries, required to fabricate the RG-AEMs, are different for each technology.Over the last decade or so, RG-AEMs with more than 100 different chemical configurations have been fabricated. Most of these have not been studied in detail as the focus was traditionally on RG-AEMs for use in alkaline membrane fuel cells where AEMs needed to have good stabilities in alkali. This has meant the focus was only on a small number of these chemistries. However, other electrochemical applications, such as electrodialysis (ED) and reverse electrodialysis (RED, a salinity gradient power technology) require AEMs to be operating in more neutral pH environments. This allows a wider range of chemistries to be used. For such applications, properties such as permselectivity and fouling resistance can be as important as ion conductivity.This presentation will provide a summary of recent RG-AEM developments at Surrey. A focus will be on the study of AEM chemistries for potential use in RED, with a study on the effects of crosslinking, head-group chemistry, and ion-exchange capacity. It has been found that despite being highly ionically conductive, non-crosslinked RG-AEMs have intrinsically low permselectivities and are prone to excessive levels of swelling in water (especially at high ion-exchange capacities). The incorporation of crosslinking can improve permselectivities, and lower swelling, but this often leads to detrimental drops in ion conductivity. Interestingly, the choice of head-group chemistry can have an effect on properties such as permselectivity.This research has been funded by EPSRC grants EP/M014371/1, EP/M022749/1, EP/R044163/1, and EP/T009233/1 along with EU Project SELECTCO2 (grant agreement 851441). Select recent references: R. Bance-Soualhi, M. Choolaei, S. A. Franklin, T. R. Willson, J. Lee, D. K. Whelligan, C. Crean, J. R. Varcoe, "Radiation-grafted anion-exchange membranes for reverse electrodialysis: a comparison of N,N,N',N'-tetramethylhexane-1,6-diamine crosslinking (amination stage) and divinylbenzene crosslinking (grafting stage)", J. Mater. Chem. A, 9, 22025 (2021) [CC-BY].K. M. Meek, C. M> Reed, B. Pivovar, K.-D. Kreuer, J. R. Varcoe, R. Bance-Soualhi, "The alkali degradation of LDPE-based radiation-grafted anion-exchange membranes studied using different ex situ methods", RSC Adv., 10, 36467 (2020) [CC-BY].T. R. Willson, I. Hamerton, J. R. Varcoe, R. Bance-Soualhi, "Radiation-grafted cation-exchange membranes: an initial ex situ feasibility study into their potential use in reverse electrodialysis", Sustainable Energy Fuels, 3, 1682 (2019) [CC-BY]L. Wang, X. Peng, W. E. Mustain, J. R. Varcoe, "Radiation-grafted anion-exchange membranes: the switch from low- to high-density polyethylene leads to remarkably enhanced fuel cell performance", Energy Environ. Sci., 12, 1575 (2019) [CC-BY].

The Latest Developments in Radiation-Grafted Anion-Exchange Polymer Electrolytes for Low Temperature Electrochemical Systems

Anion-exchange membranes (AEM) are being developed for use in electrochemical technologies including fuel cells (AEMFC),water electrolysis (AEMWE for green hydrogen), electrolysers for CO2 reduction (CO2RR), and reverse electrodialysis (RED). Radiation-grafted AEMs (RG-AEM) represent a promising class of AEM that can exhibit high conductivities (OH- conductivities of > 200 mS cm-1 at temperatures above 60 °C) and favourable in situ water transport characteristics). Hence, RG-AEMs have shown significant promise when tested in AEMFCs alongside powdered radiation-grafted anion-exchange ionomers (RG-AEI), producing high performances and promising durabilities [Energy Environ. Sci., 12, 1575 (2019) and Nature Commun., 11, 3561 (2020)], even at temperatures above 100 °C [Dekel et al., J. Power Sources Adv., 5, 100023 (2020)].An Achilles heel with RG-AEM types is that they can swell excessively in water and have large dimensional changes between the dehydrated and hydrated states. This limits the ion-exchange capacities (IEC) that can be used: excessive IECs in RG-AEM will cause excessive swelling and poorer robustness. This clearly indicates that additional crosslinking is needed. As Kohl et al. have highlighted, optimised crosslinking can lead to production of high-IEC AEMs that are both robust enough to be < 20 µm in thickness and also low swelling [e.g. J. Electrochem. Soc., 166, F637 (2019)], allowing truly world-leading AEMFC performances.RG-AEMs are also being used as a screening platform for down-selecting different (cationic) head-group chemistries for use in RED cells (a salinity gradient power technology), where different head-groups may lead to different AEM characteristics such as: in-cell resistance (when in contact with aqueous electrolytes), permselectivity, and fouling characteristics (when real world waters such as industrial brines, seawater and freshwater are used). It was evident very early on in these studies that RG-AEMs (desirably) exhibit extremely low resistances but also (undesirably) very low permselectivities when un-crosslinked (less than the required 90%+ permselectivity). Our work on RG-type cation-exchange membranes [Sustainable Energy Fuels, 3, 1682 (2019)] clearly shows that introduction of crosslinking can improve permselectivity.Crosslinking always involves a compromise, where its introduction can improve a membrane characteristic (e.g. reduced swelling or improved permselectivity) but also leads to lower conductivities or poorer transport of chemical species through the membranes. Hence, crosslinking types and levels need to be carefully controlled. With RG-AEMs (made by electron-beam activation (peroxidation) of inert polymer films, followed by grafting of monomers and post-graft amination), we have a choice of introducing crosslinking at various stages. The figure below summarises the two different approaches to crosslinking that will be discussed in the presentation: adding a divinyl-type crosslinker into the grafting mixture or adding a diamine-type crosslinker into the amination step.This presentation will present a selection of recent RG-AEM and RG-AEI developments from a number of projects:(1) REDAEM: AEMs for RED cells [EPSRC Grant EP/R044163/1];(2) CARAEM: Novel RG-AEMs for AEMFCs and AEMWE [EPSRC Grant EP/T009233/1];(3) SELECTCO2: RG-AEMs being tested in CO2RR cells [EU Horizon 2020 grant agreement 851441].This presentation will show:(a) RG-AEMs made from thin high density polyethylene (HDPE) precursors appear better for application in AEMFCs, while RG-AEMs from made from thicker ETFE precursors appear to be better for CO2RR cells and RED;(b) RG-AEMs can be made using a variety of crosslinking strategies;(c) RG-AEIs can be made using ETFE powders and give optimal performance after cryogrinding down to micrometer sizes; Figure 1

Measuring the alkaline stability of anion-exchange membranes

One significant barrier in developing durable, robust anion-exchange membranes (AEMs) for liquid-electrolyte-free fuel cells (AEMFCs) and water electrolyzers (AEMWEs) is their limited chemical stability to alkali. To measure the alkaline stability of AEMs, ex-situ tests are commonly used where the AEMs are immersed for long durations in aqueous alkali solutions. However, such tests do not adequately simulate the liquid-electrolyte-free environment of AEMFCs and AEMWEs, as the hydration and alkaline conditions do not always mimic actual operando conditions, yielding misleading and inaccurate indications of degradation rates for relatively low hydration conditions. We recently reported a unique ex-situ method which determines the alkaline stability of AEMs under conditions that mimic in-situ operating environments. In this study, we apply this technique to determine the alkaline stability of several AEMs containing different functional group and backbone chemistries. The alkaline stability of HDPE-based radiation-grafted (RG)-AEMs containing different functional group chemistries follows the trend: TMA ≥ MPY ∼ MPIP ≫ DEMA > TEA. Radiation-grafted AEMs (and a non-radiation-grafted PPO benchmark) containing different backbones and the same stable TMA group follows the stability order: ETFE ≥ LDPE > HDPE ≫ PPO. This technique is recommended for ex-situ testing of the alkaline stability of AEMs for both AEMFC and AEMWE applications.

(Invited) Cross-Linked Radiation-Grafted Anion-Exchange Membranes for Energy Conversion Systems: When to Cross-Link?

Anion-exchange membranes (AEM) are being developed for use in a wide range of electrochemical energy technologies including fuel cells (AEMFC), H2-generating electrolysers (AEM-WE), CO2 reduction cells (CO2ER), and reverse electrodialysis (RED). An interesting class of AEM is radiation-grafted types (RG-AEM), which can exhibit very high conductivities and favourable in situ water transport characteristics. Hence, RG-AEM have shown significant promise in application in AEMFCs, producing high performances and promising durabilities [Energy Environ. Sci., 12, 1575 (2019) and Nature Commun., 11, 3561 (2020)]. An Achilles heel with RG-AEM types is that they can swell excessively in water and have large dimensional changes between the dehydrated and hydrated states. This limits the ion-exchange capacities (IEC) that can be used: excessive IECs in RG-AEM will cause excessive swelling and poorer robustness. This clearly indicates that additional crosslinking is needed. As Kohl et al. have highlighted, optimised crosslinking can lead to production of high-IEC AEMs that are both robust enough to be < 20 µm in thickness and also low swelling [e.g. J. Electrochem. Soc., 166, F637 (2019)], allowing truly world-leading AEMFC performances.RG-AEMs are also being used as a screening platform for down-selecting different (cationic) head-group chemistries for use in RED cells (a salinity gradient power technology) [active UK EPSRC grant EP/R044163/1], where different head-groups may lead to different AEM characteristics such as: in-cell resistance (when in contact with aqueous electrolytes), permselectivity, and fouling characteristics (when real world waters such as industrial brines, seawater and freshwater are used). It was evident very early on in these studies that RG-AEMs (desirably) exhibit extremely low resistances but also (undesirably) very low permselectivities when un-crosslinked (less than the required 90%+). Our work on RG-type cation-exchange membranes [Sustainable Energy Fuels, 3, 1682 (2019)] clearly shows that introduction of crosslinking can improve permselectivity.Crosslinking always involves a compromise, where its introduction can improve a membrane characteristic (e.g. reduced swelling or improved permselectivity) but also leads to lower conductivities or poorer transport of chemical species through the membranes. Hence, crosslinking types and levels need to be carefully controlled. With RG-AEMs (made by electron-beam activation (peroxidation) of inert polymer films, followed by grafting of monomers and post-graft amination), we have a choice of introducing crosslinking at various stages. The figure below summarises the two different approaches to crosslinking that will be discussed in the presentation: adding a divinyl-type crosslinker into the grafting mixture or adding a diamine-type crosslinker into the amination step.This presentation will present the results from an initial investigation of these two crosslinking approaches. As well as crosslinking in the amination stage being practically easier and more repeatable (we used N,N,N',N'-tetramethyl-1,6-hexane diamine (TMHDA) as a model diamine, being readily commercially available) compared to adding divinylbenzene (DVB – a model commercially available divinyl crosslinking agent) in the grafting step, we will show that such diamine crosslinking also enhances desirable properties (such as permselectivity) with less sacrifice of conductivity (less increases in resistance) compared to the use of DVB crosslinking. Figure 1

Radiation-Grafted Anion-Exchange Membrane for Fuel Cell and Electrolyzer Applications: A Mini Review.

This review discusses the roles of anion exchange membrane (AEM) as a solid-state electrolyte in fuel cell and electrolyzer applications. It highlights the advancement of existing fabrication methods and emphasizes the importance of radiation grafting methods in improving the properties of AEM. The development of AEM has been focused on the improvement of its physicochemical properties, including ionic conductivity, ion exchange capacity, water uptake, swelling ratio, etc., and its thermo-mechano-chemical stability in high-pH and high-temperature conditions. Generally, the AEM radiation grafting processes are considered green synthesis because they are usually performed at room temperature and practically eliminated the use of catalysts and toxic solvents, yet the final products are homogeneous and high quality. The radiation grafting technique is capable of modifying the hydrophilic and hydrophobic domains to control the ionic properties of membrane as well as its water uptake and swelling ratio without scarifying its mechanical properties. Researchers also showed that the chemical stability of AEMs can be improved by grafting spacers onto base polymers. The effects of irradiation dose and dose rate on the performance of AEM were discussed. The long-term stability of membrane in alkaline solutions remains the main challenge to commercial use.

Radiation-grafted anion-exchange membranes for reverse electrodialysis: a comparison ofN,N,N′,N′-tetramethylhexane-1,6-diamine crosslinking (amination stage) and divinylbenzene crosslinking (grafting stage)

Fabricating crosslinked radiation-grafted anion-exchange membranes using a diamine in the amination synthesis step leads to a better permselectivity-resistance balance compared to the use of divinylbenzene in the grafting step.

Fabrication of cellulose acetate‐based radiation grafted anion exchange membranes for fuel cell application

AbstractNovel cellulose acetate‐based anion exchange membranes (CA‐AEM) are successfully synthesized via gamma radiation grafting as a possible renewable alternative to commercial AEMs. Using CA film precursors with degree of acetylation of 2.5, the synthesized AEM shows a high ion exchange capacity of 2.15 mmol g−1 obtained at high degree of grafting of 45%. It was determined using thermogravimetric analysis that the radiation‐grafted CA‐AEM has stable amine functional groups under oxygen environment within the normal operating temperature range of alkaline fuel cells. The CA‐AEM also exhibits appreciable performance over a range of temperatures, with a highest ionic conductivity of up to 0.163 S cm−1 depending on the synthesis parameters. Results revealed that membranes prepared using gamma radiation dose of 31 kGy and above are susceptible to mechanical and dimensional instability due to increased water uptake and degree of swelling. Further study should consider the balance between grafting parameters and the desired hydrophysical properties.

A Raman Spectroscopic Study of Radiation-Grafted Anion-Exchange Membranes Containing Different Anions

Anion exchange membranes (AEM) are being developed for use in a variety of electrochemical energy systems, such as alkaline membrane fuel cells, AEM-based electrolysers, reverse electrodialysis (RED), and redox flow batteries (RFB). The AEMs used will contain a variety of anions, depending on the application. For fuel cells and electrolysers (H2 generating or CO2 conversion), then alkaline anions such as OH-, CO3 2-, and HCO3 - are important. For RED cells and RFBs, non-alkali anions such as Cl-, HSO4 -, and SO4 2- are more relevant. If an AEM is synthesised using a methyl iodide reaction, then monitoring the ion-exchange of the resulting "as-synthesised" I- forms to other forms, such as Cl-, is important as it is well known that it can be difficult to completely ion-exchange soft anions such as I- out of AEMs (particularly those containing aromatic cationic groups).This presentation will highlight some initial results obtained from an on-going Raman spectroscopic study of radiation-grafted AEMs (RG-AEM). This study was initiated to see if Raman spectro-microscopy can be used to identify the anion form of a RG-AEM by looking at the shifts and intensity changes of Raman peaks as a function of anion. The RG-AEMs will be made from either the grafting of vinylbenzyl chloride onto ETFE (followed by reaction with amines such as trimethylamine, imidazole and pyridine) or the grafting of alternative monomers such as vinylpyridine onto ETFE (followed by reaction with methyl iodide).The below Figure shows Raman spectra (Renishaw inVia Raman microscope: 785 nm laser, 1800 lines mm-1 grating, and x20 objective giving a Airy spot diameter of ca. 3 μm) of a RG-AEM made from the grafting of vinylpyridine onto ETFE films (with a final methyl iodide reaction) in both the I- and Cl- forms (three spectra each):. Figure 1

The alkali degradation of LDPE-based radiation-grafted anion-exchange membranes studied using different ex situ methods.

Radiation-grafted anion-exchange membranes (RG-AEM) in alkaline membrane fuel cells (AEMFC) exhibit promising performances (low in situ resistances, high power outputs and reasonably high alkali stabilities). Much research is focused on developing AEMs with enhanced chemical stabilities in the OH−-forms at temperatures >60 °C. This study contributes towards this effort by providing a comparison of three different ex situ methods of screening alkali stabilities (where different laboratories conducted experiments on exactly the same batches of RG-AEM). Vinylbenzyl chloride monomer was radiation-grafted onto 25 μm thick low-density polyethylene (LDPE) precursor film in a single batch. This batch of grafted membrane was then split into three sub-batches, which were converted into RG-AEMs via amination with either: trimethylamine (TMA), N-methylpyrrolidine (MPY), or N-methylpiperidine (MPIP). Samples of each RG-AEM (l-AEM-TMA, l-AEM-MPY, and l-AEM-MPIP) were then distributed between the three collaborating institutes for evaluation using each institutes' test protocols. Out of the three head-group chemistries, the l-AEM-TMA generally exhibits the best balance of conductivity and ex situ alkali degradation, especially in lower humidity environments. The l-AEM-TMA also exhibited interestingly high Cl− ion conductivities (ca. 100 mS cm−1) when heated to 80 °C in a relative humidity RH = 95% atmosphere, a measurement frequently overlooked in favour of determining conductivities of RG-AEMs submerged in water (conductivities of submerged RG-AEMs can be suppressed due to excessive water contents and swelling).

The First Durable Imidazolium-Based Radiation Grafted Anion Exchange Membranes for Alkaline Fuel Cells: The Impact of Water Management

Recently, Radiation grafted anion exchange membranes (AEM) gained increasing interest for alkaline fuel cell applications due to their high performance such as the highest power density ever reported for alkaline fuel cells (>2W/cm2). 1 However, their durability under operating fuel cell conditions still the biggest challenge.2 In our group, several radiation grafted AEMs, having several imidizalium-based graft-polymers consisting of N-vinyl (NVIm), 2-methyl-1-vinyl- (NVMIm), 2-methyl-4-vinyl- (4VMIm), and 2-(4-ethenylphenyl)-imidazolium (2StIm) graft-polymers, have been developed.3,4 In this work, the durability of the membrane-electrode-assembly (MEA) consisting imidazolium based radiation grafting AEMs under the supply of H2 and O2 at 60 °C was investigated in comparison to the MAE with common benzyl trimethylammonium (BTMA) based membranes. The core of this study is to investigate the effect of water management and specifically the dew point of the flow gas at anode and cathode sides on the performance and durability of imidazolium based membranes. For example, by tuning the due points for NVMIm-AEM the maximum power density increased from 115 to 200 mW/cm2. On the other hand, In spite of the low durability of 4VMIm membranes under in-situ alkaline durability in solution,5 the 4VMIm retained 75 % of the initial voltage after 240 h under fuel cell conditions, that was more durable than BTMA-based MEA (Figure 1). This study reveals the main role of water management of AEMs not only on the performance but also on the membrane durability. The study discloses an alternative durable AEMs for the new generation of alkaline fuel cells and other energy applications.

(Invited) Novel Insights in the Activity, Selectivity and Durability of Fenc, Mn-Oxides and Fenc/Mn-Oxide Composites for ORR Catalysis in Alkaline Electrolyte and AEMFC

While high power densities are reached with proton-exchange membrane fuel cells (PEMFCs), several drawbacks hold their large-scale commercialization. In particular, the sluggish oxygen reduction reaction (ORR) at the cathode requires significant amount of platinum. Among PGM-free catalysts, iron-nitrogen-carbon catalysts have hitherto shown the highest initial activity toward ORR and especially those that have been subjected to NH3 pyrolysis. However their performance in PEMFC decays too fast. In contrast, prospects for active and durable Fe-N-C catalysts competitive to Pt catalysts are good in alkaline environment, and the advent of high performance anion exchange membrane (AEM) now offers the possibility to investigate this in AEM fuel cell (AEMFC). This presentation will first report on the ORR activity, stability and operando spectroscopic identification of Fe-N-C catalysts in alkaline electrolyte, with materials comprising only FeNx moieties. To further increase the ORR selectivity toward water formation, the activity and stability of different Mn-oxide polymorphs for ORR and hydrogen peroxide electro-reduction (HPRR) were studied. The properties of a composite comprising the most stable Mn-oxide and Fe-N-C material were also studied, confirming that HPRR is facilitated when Mn2O3 is added to Fe-N-C. At the same time, however, we show that HO2 - is harmful to the MnOx catalyst itself, increasing the manganese dissolution. FeNC and FeNC/Mn2O3 cathodes were then tested in AEMFC based on radiation-grafted AEM and AEI and compared to performance obtained with a Pt-based cathode. The results show high and comparable ORR activity at 0.9 V between cathodes based on 1.0-1.5 mgFeNC cm-2 and 0.4-0.5 mgPt cm-2. Peak power densities in the range of 1.1-1.7 W·cm-2 were reached in O2-fed AEMFC with such FeNC cathodes, depending on the operating conditions. Results from stability testing are also very promising, and in strong contrast to instability of the same FeNC material in PEMFC. While some performance gap still remains at high power density between highly Pt-loaded cathode and such FeNC cathode, the results show a promising application of FeNC for high performance AEMFC. Acknowledgements: The project CREATE leading to these results has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No 721065.

Improving the Long-Term Operational Stability (>1000h) of AEMFCS By Understanding Water Dynamics through in-Situ Neutron Imaging and X-Ray Computed Tomography

Over the past few years, significant progress has been made in the performance of AEMFCs. Now, it is almost routine to find AEMFCs that report peak power densities that exceed 1 W/cm2, and there are regular reports of AEMFCs operating near 2 W/cm2 [1–3] and one recent study that achieved 3.4 W/cm2. [4] Much of this progress has been made through electrolyte development, electrode understanding and a new understanding of AEMFC water dynamics. However, one big challenge that remains in AEMFC is cell stability [5], and very few studies have been reported that can achieve more than 100h durability at relevant current densities (³ 600 mA/cm2). The DOE target for AEMFC durability is 2000 h operation at ³ 600 mA/cm2 with less than 10% voltage degradation and a final cell voltage > 0.6 V. The challenges in achieving this target come from multiple aspects, such as development of a robust ionomer and membrane with high ion exchange capacity and ionic conductivity, the design of electrodes that are specifically designed for water management, and proper operating conditions. Our group has consistently shown that the performance of AEMFCs utilizing extremely hydrophilic components (particularly the ionomer) can be very high, but that performance can be sensitive to operating conditions (current density and reacting gas dew points). The conditions for cell operation can drastically change the water distribution in the catalyst layers, membrane, and gas diffusion layers [6,3]. Hence, electrode design is a critical piece to managing water and achieving good performance. [3,7] In this work, our team uses operando neutron imaging coupled with operando micro X-ray computed tomography to further study the water dynamics in AEMFCs under different operating conditions. The results showed the effects of cell operating conditions – from flooding in the anode at high current density which led to severe ionomer swelling to very low water content in the cathode during low current, low RH operation. The high-resolution neutron images indicated the existence of water back diffusion from anode to cathode, which helps to balance the cell water, but it was found that the conditions that lead to the highest possible power density are also conditions where the cell may not be stable from a water perspective for 100’s of hours. In short, to enable very long-term operation, the AEMFCs need to be operated at high reacting gas dew point. With our previous electrodes, optimized for peak power density at lower dew points, extensive cell flooding was observed at higher dew points during cell operation. Therefore, our team developed new electrode structures based on this feedback – manipulating the catalyst layer and gas diffusion layer hydrophobicity. The result was AEMFCs that are able to achieve over 1000h continuous operation at 600 mA cm-2 under H2/Air (CO2-free) at 65 °C. During this test, the cell voltage lost only 6% of its initial value at an average rate of 0.019 mV/h, which far exceeds the literature state-of-the-art for AEMFC durability. These electrodes were also capable of high peak power. The AEMFC power density and durability are shown in the figure below. The purpose of this presentation is to detail the cell-level phenomena during different operating conditions and the electrode designs that allowed for the best performance and durability. Reference: Wang, L.; Varcoe, J.R. Switching from Low-Density to High-Density Polyethylene As a Base Material for Radiation-Grafted Anion-Exchange Membranes Leads to Much Higher Alkaline Membrane Fuel Cell Performances. 235th ECS Meeting. 2019.Wang, L.; Magliocca, E.; Cunningham, E.L.; Mustain, W.E.; Poynton, S.D.; Escudero-Cid, R.; Nasef, M.M.; Ponce-González, J.; Bance-Souahli, R.; Slade, R.C.T.; et al. An optimised synthesis of high performance radiation-grafted anion-exchange membranes. Green Chem. 2017, 19, 831–843.Omasta, T.J.; Park, A.M.; LaManna, J.M.; Zhang, Y.; Peng, X.; Wang, L.; Jacobson, D.L.; Varcoe, J.R.; Hussey, D.S.; Pivovar, B.S.; et al. Beyond catalysis and membranes: visualizing and solving the challenge of electrode water accumulation and flooding in AEMFCs. Energy Environ. Sci. 2018, 11, 551–558.Kohl A, P.; Garrett, H.; Mandal, M. High Conductivity, Stable Anion Conducting Membranes Based on Poly(norbornene). 235th ECS Meeting. Dekel, D.R. Review of cell performance in anion exchange membrane fuel cells. J. Power Sources 2018, 375, 158–169.Omasta, T.J.; Wang, L.; Peng, X.; Lewis, C.A.; Varcoe, J.R.; Mustain, W.E. Importance of Balancing Membrane and Electrode Water in Anion Exchange Membrane Fuel Cells T. J. Omasta. J. Power Sources 2017, 1–26.Omasta, T.J.; Zhang, Y.; Park, A.M.; Peng, X.; Pivovar, B.; Varcoe, J.R.; Mustain, W.E. Strategies for Reducing the PGM Loading in High Power AEMFC Anodes. J. Electrochem. Soc. 2018, 165, F710–F717. Figure 1

(Invited) Switching from Low-Density to High-Density Polyethylene As a Base Material for Radiation-Grafted Anion-Exchange Membranes Leads to Much Higher Alkaline Membrane Fuel Cell Performances

This presentation will describe the development of a new type of radiation-grafted anion-exchange membrane (RG-AEM) made from high-density polyethylene (HDPE) base material, which contains benzyltrimethylammonium cationic head-group chemistry. This RG-AEM has an ion-exchange capacity (IEC) of 2.4 meq g-1, and is less than 30 μm in thickness (when fully hydrated) with an ultimate tensile strength of ca. 35 MPa (elongation to break of 280 %). It exhibits a hydroxide conductivity of 214 ± 2 mS cm-1 at 80 °C in a 100% relative humidity (RH) atmosphere, which decays to 195 mS cm-1 after 500 h exposure to these same ex situ conditions. Despite exhibiting similar ex situ characteristics to a low-density polyethylene (LDPE) analogue RG-AEM (of similar hydrated thickness and IEC), the HDPE-RG-AEM yields significantly higher beginning-of-life H2/O2-benchmark alkaline membrane fuel cell power densities (see Figure): 2.55 W cm-2 peak power density was achieved at 80 °C with 92% RH H2/O2 gas supplies (no back pressure applied). Internal area specific resistances of < 30 mΩ cm2 were recorded. Figure 1

Radiation-grafted anion-exchange membranes: the switch from low- to high-density polyethylene leads to remarkably enhanced fuel cell performance

Radiation-grafted HDPE-based anion-exchange membranes perform better than LDPE-based benchmarks despite exhibiting similar ex situ properties.