2.1. Membrane Development
The AEM, comprising an anion exchange cationic group linked to a polymer backbone, is a key constituent that determines the AEMWEs’ performance and lifetime. The mechanical and thermal stability is related to the polymer backbone chemistry, whereas the ionic conductivity is influenced by the cationic functional groups. The chemical stability is influenced by both the polymer backbone and the functional groups [
7]. There are several AEMs commercially available, and others developed “in-house”, reported in the literature. The polymer backbone is frequently a polysulfone, crosslinked polystyrene with divinyl benzene (DVB), or polyaromatics [
7]. For example, poly(fluorenyl aryl piperidinium)-, polycarbazole-, and polyphenylene-based AEMs were tested in cells attaining current densities as 2.3, 2.57, and 5.3 Acm
−2, respectively, measured at 1.8 V, presenting good durability [
4]. The cationic functional groups are generally quaternary ammonium (QA) or imidazolium (IM). Some suppliers commercialize AEMs, such as: Tokuyama (A201) (discontinued production), Fumatech (FumasepR), Ionomer (Aemion
TM), Dioxide Materials (Sustainion
®), and Orion Polymer (Orion
TM). There are research-based membranes, e.g., Versogen (PiperION) and Xergy (XION™ Ion Exchange Membranes), which are promising alternatives to overtake commercial membranes. Nevertheless, they are offered on the market, although they are costly due to their small production scale and are not cost-competitive with commercial ones. In addition, more studies regarding durability under severe conditions are needed [
4].
Liu et al. [
14] tested the performance of an AEMWE at 60 °C with different commercial membranes: Sustainion
® 37-50, Fumasep FAS-50, Fumasep FAPQ, Neosepta ACM, AMI 7001, Nafion
® 115, and Celazole
® PBI. Better results were found using Sustainion
® 37-50 membranes, operating at 1 Acm
−2 at about 1.9 V for 2000 h. The other membranes presented a high area-specific resistance (ASR) or a higher degradation rate under the tested conditions.
Henkensmeier et al. [
11] published a very interesting paper, giving an overview of the commercial AEMs (Fumatech Fumasep
® FAA3, Tokuyama A201, Ionomer Aemion™, Dioxide Materials Sustainion
®, and membranes commercialized by Orion Polymer, Cohoes, NY, USA), and reviewed their properties and performances in AEMWE. The authors concluded that all materials (membrane, ionomer, catalyst, cell design, etc.) must be optimized together. Consequently, it is difficult to precisely rank the commercial membranes by analyzing the available literature data, limiting an experimental rank to a system. As an overall tendency, however, the membranes FAA3 and A201 presented a lower ion conductivity than the novel membranes Aemion and Sustainion
®.
Fortin et al. [
15] tested Aemion™ AEMs (all-hydrocarbon) with several ion-exchange capacities and thicknesses. The authors reported that better results were obtained using the AEM AF1-HNN8-50, with a thickness of 50 μm, achieving current densities of 2 Acm
−2 at a potential of 1.82 V using 1 M KOH at 60 °C.
Kang et al. [
16] used an AEM without an aryl-ether backbone structure (Orion-TM1
TM). The authors reported that this membrane contains quaternary ammonium as a functional group and polyphenylene as the backbone, presenting a high ionic conductivity and stability, performing better and being more durable than the conventional AEM (FAA-3). Additionally, it showed high efficiency using pure water as a feed solution. The optimized TM1-MEA attained a current density of 2.75 Acm
−2 at 1.9 V with great stability of 55 mV h
−1, benefiting from the superior structural advantages of the Orion-TM1™ membrane. The aryl-ether-free structure and hydrophobic properties inhibited decomposition by ether hydrolysis and prevented the attack of hydrophilic hydroxide ions.
Lv et al. [
9] developed a quaternary ammonium poly (n-methyl-piperidine-co-p-terphenyl) (QAPPT) and Ni-Fe layered double hydroxide (LDH) composite membrane. The QAPPT/3% Ni-Fe LDH composite membrane exhibited a great performance of 1 Acm
−2 at the voltage of 1.824 V at 60 °C, superior to most of the ones reported in the literature. Moreover, a long-term stability test was conducted at 500 mAcm−2 for more than 87 h, achieving a reasonable performance.
As explained in the introduction, the MEA, comprising not only the membrane but also ionomer, anode, and cathode catalyst layers and GDLs, needs to be optimized. A recent review [
9] explained the most common methods used to produce MEAs, catalyst-coated membrane (CCM), and catalyst-coated substrate (CCS) methods. The commonly implemented hot-press method used in PEM cells was not a good option in AEMWEs because i) the degree of mechanical force and high temperature induces irreversible damage to the membrane due to the use of metallic GDLs, and ii) hydrocarbon ionomers do not have an accessible glass transition (cannot be effectively fused by hot-pressing). This may lead to performance losses and degradation generated by insufficient contact and/or gradual delamination between the membrane/catalyst layer interface. Catalyst–ionomer interaction and loading content optimization are crucial for the advances in AEMWEs [
17]. Engineered MEAs must be developed, aiming for effective contact between membrane/catalyst/ionomer/GDL.
2.2. Non-PGM Catalyst Development
Theoretically, due to a high pH environment, AEMWE can permit the substitution of PGM electrocatalysts with Earth-abundant first-row transition metals (e.g., Mn, Fe, Ni, Cu, and Mo) to catalyze OER and HER reactions. Currently, IrO
2, Ni, Ni-Fe alloys, graphene, Pb
2Ru
2O
6.5, and Cu
0.7CO
2.3O
4 are used as OER catalysts, while Pt black, CuCoOx, Ni-Mo, Ni/CeO
2-La
2O
3/C, Ni, and graphene could be used as HER catalysts [
2]. Ir and Pt could be replaced by Fe, Ni, Mn, Cu, and Mo, considerably decreasing the prices of the global system. PGM-free electrocatalysts are already used to catalyze OER, with Ni-based electrocatalysts, which are currently state-of-the-art. However, for the HER, the state-of-the-art electrocatalysts are still based on precious metals [
4].
Sulaiman et al. [
13] wrote a complete review paper with an overview of the latest electrocatalysts for HER and OER. The authors reported that transition metal catalysts with very good electrocatalytic properties can play a role in improving AEMWE performance. For instance, the NiMo-NH
3/NH
2 for HER coupled with a Fe-NiMo-NH
3/NH
2 for OER reached 1 Acm
−2 at 1.57 V. Li et al. [
3] illustrated that OER kinetics can be influenced by a higher catalyst loading at the anode, and a lower utilization rate, particularly when the concentration of hydroxyl ions in the electrolyte has diminished, and active sites on the catalyst have been blocked by the inevitable high pressure of gas evolved in the MEA. The authors also stated that Ni-Mo alloyed materials, Co
3O
4 nanocrystals, Fe, and Ni-Fe alloys are good candidates to improve OER performance; however, stability through a period of one thousand hours needs to be confirmed. Sulaiman et al. [
13] reported that bifunctional (the same for HER and OER reactions) catalysts should be investigated, making a simpler electrode system. For OER, many of the reported studies demonstrated high activity and efficiency of transition metal-based catalysts, predominantly NiFe-based, however, the majority still present high overpotentials beyond 200 mV, at 10 mAcm
−2 [
13]. The high overpotentials are associated with the slow and difficult OER mechanism [
3]. Considering HER electrocatalysts, the use of transition metals is still challenging because most of these catalysts are not as active as Pt/C. HER is also slower in alkaline media than in acid media [
18]. Consequently, to decrease the overpotential and improve the activity of HER transition metal catalysts, there is a need to understand their reaction mechanism related to the adsorption of water molecules and bond breaking. One possible approach, reported by Li et al. [
3], is the addition of heteroatoms, such as N-doping, possibly lowering the adsorption-free energy, facilitating HER. In addition, their stability and efficiency must be confirmed for real-world applications.
2.3. Durability
Most existing AEMWE components, especially membranes and catalysts, are not robust enough considering industrial targets due to chemical and mechanical degradation. This scenario is prone to change with intensive research and a few promising alternatives.
The causes of AEMWE performance losses include membrane degradation. It is well-known that the hydroxide anions attack the positively charged cations in the AEM, neutralizing them [
4]. This leads to a loss of anion-exchange functional groups and, consequently, a decrease in OH− conductivity generating higher ohmic resistances [
19]. Additionally, continued thermal and chemical degradation of ionomers could reduce the connection to the catalysts, decreasing the reaction rate [
13]. The ionomer ionic conductivity is better using a high number of ion-exchange groups, but this situation intensifies the water uptake originating the ionomer dissolution at higher temperatures. The catalyst activity may also become worse through catalyst dissolution, particle coalescence (catalyst agglomeration), Ostwald ripening, support corrosion, and adsorption of ionomer moieties [
7].
Motealleh et al. [
20] demonstrated a good performance, considering industrial parameters using Sustainion
® membranes. Durability tests exhibited a stable performance of 1 A.cm
−2 at 1.85 V with a degradation rate below 1 mV/h over 10,000 h, leading to an estimated lifetime of about 20 years. Moreover, the authors reported that it is possible to increase the mechanical stability of a Sustainion
® membrane through the addition of zirconia to the polymer matrix.
Henkensmeier et al. [
11] determined that stability is intrinsically related to the system. The authors pointed out that a reliable prediction of membranes’ lifetime is necessary. Since durability tests usually need up to 10,000 h, it is necessary to develop ASTs, as was performed for PEM Fuel Cells. Durability tests using ASTs to determine components’ aging are crucial to attaining the industrial standard requirements. Overall, despite stability being recognized as a bottleneck, there is weak knowledge about the lifetime of optimized systems.
Bearing in mind catalyst stability, they must have a lifetime of more than 1000 h and keep their efficiency when operating at high current densities and under repeated on-off cycles from RES [
13].
2.4. Feeding Solutions
In AEMWE, deionized water, ultrapure water, 1 wt.% K
2CO
3, and 1 M KOH have all been used as reactants [
3]. Hydroxide solutions are used as an alternative to pure water to feed AEMWE to increase the ionic conductivity of the AEM because resistance losses decrease almost linearly (in a limited range of concentrations) when increasing electrolyte concentration [
21]. However, higher hydroxide concentration conducts in elevated corrosion rates, reducing the lifetime of AEMWEs [
7]. Better performances have been reported using 1 M KOH [
2]. The predicted hydrogen demand in the distant renewable future is 2.3 Gt per year [
22]. Considering the reaction stoichiometry, for every kg of hydrogen produced, 9 kg of water must be consumed. Therefore, 2.3 Gt of hydrogen requires 20.5 Gt, or 20.5 billion m
3 of water [
23]. Although in other sectors, i.e., agriculture, more water is used than necessary for the most ambitious scenario for hydrogen, the scarcity of freshwater limits its use. As mentioned before, the feeding condition significantly impacts on the electrocatalytic activity and, consequently, AEMWE performance.
The use of demineralized water is the most preferred option to make AEM electrolysis a competitive technology. Nevertheless, using pure water carries critical new challenges. Ni is currently the standard material for electrode construction in AEM electrolysis. However, under anodic polarization, it is stable only at a pH higher than 9, conditioning the use of a pure water feed without performance degradation. Another problem with using deionized water, also occurring using hydroxide solutions, is the negative influence of CO
2 on performance. Parrondo et al. [
24] described that this phenomenon was due to dissolved carbonate and bicarbonate anions that diminish the ionic conductivity of the membrane and catalytic layer binders.
The use of impure water in AEMWE is also an important research topic. Even if most pollutants in wastewater are successfully removed by the current wastewater treatment processes, small quantities of impurities (residual organics and ions) remain in the treated water. No studies show how the impurities affect water electrolyzer performance and durability, despite studies reporting how impurities affect either the membrane or electrode. There is a need to understand more fully the impact of water impurities present in wastewater on the performance and durability of AEMWE. For example, despite the fact that most cationic impurities have undesirable effects during electrolysis, cationic Fe impurities seem to be essential to stabilize OER activity in alkaline conditions with Earth-abundant catalysts [
6]. Zou et al. [
25] reported that Fe cations intensely improve OER activity when incorporated substitutionally into Ni or Co (oxy)hydroxides, acting as possible OER active sites. However, pure Fe (oxy)hydroxide is not a good catalyst for OER, and its effect still needs to be better understood. Cation poisoning can be avoided by adjusting the water flow rate and current density to minimize co-ion transport or through engineering approaches. It is also important to understand the relationships between the morphology, composition, and phase of the catalyst material and its durability in impure water AEM electrolysis. Analysis of Chemical Oxygen Demand (COD), Total Organic Carbon (TOC), and several metals (i.e., zinc, copper, iron) present in treated wastewater will be necessary to identify its composition. If CO
2 (previously identified as a detrimental compound) is present, it must be removed before using the wastewater. It is also possible that supplementary water treatments will be needed to eliminate specific impurities affecting AEMWE performance and durability. For example, precipitation or adsorption treatments could be able to remove undesirable metals.
Another possible solution is the use of seawater to feed AEMWEs. However, this latter approach leads to a side reaction, competitive with OER: the chloride oxidation reaction (ClER). Park et al. [
26] thoroughly explained this competition and how to avoid/minimize it. The authors suggested that to achieve high OER selectivity, seawater electrolysis should be performed below 1.72 V
RHE under alkaline conditions, and a more active electrocatalyst for the OER is essential to attain highly efficient seawater electrolysis in an overvoltage range of less than 490 mV.
Few studies reported the use of other feeding solutions than hydroxide solutions.
Park et al. [
26] tested an AEMWE using a Ni-doped FeOOH catalyst, tested in 1.0 M KOH + seawater, demonstrating a current density of 729 mA cm
−2 and an energy conversion efficiency of 76.35%. Compared to reported AEM electrolyzers operated in 1.0 M KOH, the Ni-doped FeOOH operated in 1.0 M KOH + seawater still exhibited a higher performance.
Lindquist et al. [
27] performed a study with an AEMWE made of commercially available materials, operating near 1.9 V at 1 A cm
−2 in pure water. This study highlights that improving hydroxide conductivity, mass transport, and long-term ionomer stability are crucial for developing pure-water AEM electrolyzers.