Hydrogen is an important part of any discussion on sustainability and reduction in emissions across major energy sectors. In addition to being a feedstock and process gas for many industrial processes, hydrogen is emerging as a fuel alternative for transportation applications. Renewable sources of hydrogen are therefore required to increase in capacity. Low-temperature electrolysis of water is currently the most mature method for carbon-free hydrogen generation and is reaching relevant scales to impact the energy landscape. However, costs still need to be reduced to be economical with traditional hydrogen sources. Operating cost reductions are enabled by the recent availability of low-cost sources of renewable energy, and the potential exists for a large reduction in capital cost withmaterial and manufacturing optimization. This article focuses on the current status and development needs by component for the low-temperature electrolysis options.
Electrocatalysts are nanomaterials of paramount importance within water electrolyzers, because they facilitate the electron transfer between reactants and electrode, enabling the chemical transformation of water into hydrogen and oxygen. In this Perspective, recent findings in electrocatalyst development for the next generation of polymer electrolyte membrane (PEM) water electrolyzers at scale are discussed. We discuss opportunities to create catalyst architectures, the importance to demonstrate electrode manufacturing tools, and how useful advanced characterization methods shall, in the short term, allow large-scale deployment of water splitting devices with higher efficiency, acceptable durability, and low cost. We envision next-generation PEM cells permitting a transformational change in the chemical industry by the manufacturing of low-cost hydrogen.
Proton exchange membrane water electrolyzers (PEMWEs) have demonstrated enormous potential as the next generation hydrogen production technology. The main challenges that the state-of-the-art PEMWEs are currently facing are excessive cost and poor durability. Understanding the failure modes in PEMWEs is a key factor for improving their durability, lowering the precious metal loading, and hence cost reduction. In this work, reactive spray deposition technology (RSDT) has been used to fabricate a membrane electrode assembly (MEA) with one order of magnitude lower Pt and Ir catalyst loadings (0.2-0.3 mgPGM cm-2) in comparison to the precious metal loadings in the stat-of-the-art commercial MEAs (2–3 mgPGM cm-2). As fabricated MEA with an active area of 86 cm2, has been tested for over 5000 hours at steady-state conditions that are typical for an industrial hydrogen production system. Herein, we present and discuss the results from a comprehensive post-test analysis of the MEA of interest. The main degradation mechanisms, governing the performance loss in the RSDT fabricated MEA with ultra-low precious metal loadings, have been identified and discussed in detail. All failure modes are critically compared and the main degradation mechanism with the highest impact on the MEA performance loss among the others is identified.
The porous transport layer is an important component of low-temperature electrolysis devices, such as proton exchange membrane water electrolyzers or anion exchange membrane water electrolyzers. PTLs have significant influence on the cell performance as their bulk resistance can impact the ohmic resistance, their contact resistance can impact electrode performance, and their structure can impact the liquid flow to the cell, which could cause mass-transport losses. In order to improve cell performance, optimization of the PTL is critical. Standardized protocols should be utilized to adequately compare PTLs being developed from different institutions. This method will detail a standardized protocol for measuring the resistance of the PTL using a four-wire setup and will also detail a process for measuring the porosity and water contact angle of the PTL using capillary flow porometry.
Accurate and reproducible screening of the electrocatalytic activity of novel materials for Oxygen Evolution Reaction (OER) and Hydrogen Evolution Reaction (HER) requires establishing an easily adoptable harmonized testing protocol. Herein, we describe a robust, instrumentation-independent testing technique utilizing a three-electrode cell with a fully immersed working electrode. Compared to rotating disk electrode (RDE) techniques, this protocol produces current densities close to those obtained in real electrolyzers and eliminates the usage of the expensive RDE apparatus.
Development
of novel technologies for catalyst synthesis and membrane
electrode assembly (MEA) fabrication is of primary importance for
further improvement of the performance and economics of proton exchange
membrane fuel cells (PEMFCs) and proton exchange membrane water electrolyzers
(PEMWEs). While the traditional manufacturing methods are time-consuming,
energy intensive, and require many processing steps, newer vapor-based
methods provide many benefits including the development of improved
catalysts and catalyst supports, deposition of uniform thin films,
reduction of catalyst loading, and minimizing the number of manufacturing
steps. Recent publications in the field identified spray pyrolysis,
reactive spray deposition technology, chemical vapor deposition, and
atomic layer deposition as advanced vapor-based catalyst synthesis
and deposition methods used for fabrication of MEAs for PEMFCs and
PEMWEs. The MEAs fabricated via vapor-based processes have shown significant
performance improvements in comparison to the state-of-the-art MEAs,
which are attributed to better catalyst distribution, improved catalyst
supports, and controlled, uniform catalyst layer microstructures.
This review provides an overview of the vapor-based synthesis and
deposition methods currently being used for the development of PEM-based
devices. The advantages and disadvantages of these methods are critically
compared and discussed while the outlook for future development is
provided.
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