Effects of Bifunctional Oxygen Catalyst Layer Composition on Unitized Regenerative Fuel Cell Performance

Christopher P. Rhodes, Jose Fernando Godinez Salomon, Michael E. Urena
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Abstract

Proton exchange membrane unitized regenerative fuel cells (PEM-URFCs) can generate storable fuel (hydrogen) and oxidant (oxygen) which can then be used to produce power from the same cell. Combining electrolysis and fuel cell modes within the same cell allows PEM-URFCs to have the potential for lower mass, volume, and cost compared with discrete fuel cell and electrolyzer systems. The bifunctional oxygen catalyst layer (BOCL) catalyzes the oxygen evolution reaction (OER) and the oxygen reduction reaction (ORR) at the same electrode, and there are wide potential differences and opposing mass transport phenomena involved within the BOCL when operating in electrolyzer or fuel cell mode. The BOCL composition, structure and morphology significantly affect performance and stability of PEM-URFCs. In our prior work, we showed bimetallic nanoframes provide bifunctional oxygen electrocatalysts with significantly higher activity compared with monometallic structures, evaluated using a rotating disk electrode configuration. 1 We will present our investigation of the effects of the BOCL composition, structure and morphology on URFC membrane electrode assemblies (MEAs) prepared using ultrasonic spraying. Catalyst composition and loading were determined to influence URFC performance, and there are tradeoffs between fuel cell performance, electrolyzer performance, and catalyst cost. In addition to the effects of the active catalyst (either Pt for ORR or IrO 2 for OER), our work supports the non-catalytically active component influences MEA performance, which is in agreement with our finding of synergistic effects of Pt and IrO 2 within rotating disk electrode measurements. 1 We are also evaluating the effects of porous transport layers and different operating conditions on URFC MEA performance and durability over repeated cycling. References Godínez-Salomón, F.; Albiter, L.; Mendoza-Cruz, R.; Rhodes, C.P. Bimetallic Two-dimensional Nanoframes: High Activity Acidic Bifunctional Oxygen Reduction and Evolution Electrocatalysts. ACS Appl. Energy Mater. 2020, 3 , 2404-2421 .
双功能氧催化剂层组成对单体再生燃料电池性能的影响
质子交换膜单元化再生燃料电池(PEM-URFCs)可以产生可储存的燃料(氢)和氧化剂(氧),然后可以使用同一电池产生电力。与分离的燃料电池和电解槽系统相比,在同一电池中结合电解和燃料电池模式,使pem - urfc具有更低的质量、体积和成本的潜力。双功能氧催化剂层(BOCL)在同一电极上催化析氧反应(OER)和氧还原反应(ORR),在电解槽或燃料电池模式下,BOCL内部存在较大的电位差和相反的质量传递现象。BOCL的组成、结构和形态显著影响pem - urfc的性能和稳定性。在我们之前的工作中,我们发现双金属纳米框架提供了双功能氧电催化剂,与单金属结构相比,具有更高的活性,使用旋转圆盘电极配置进行评估。我们将研究BOCL的组成、结构和形态对超声喷涂制备的URFC膜电极组件(MEAs)的影响。催化剂的组成和负载会影响URFC的性能,并且需要在燃料电池性能、电解槽性能和催化剂成本之间进行权衡。除了活性催化剂的影响(无论是Pt对ORR还是io2对OER),我们的工作支持非催化活性成分影响MEA性能,这与我们在旋转圆盘电极测量中发现的Pt和io2的协同效应一致。我们还评估了多孔传输层和不同操作条件对URFC MEA性能和重复循环耐久性的影响。参考文献Godínez-Salomón, F.;钠长石、l;Mendoza-Cruz r;双金属二维纳米框架:高活性酸性双功能氧还原和进化电催化剂。ACS达成。能源工程学报,2020,32(3):2440 -2421。
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