TY - JOUR
T1 - Application of Thermal Spray Coatings in Electrolysers for Hydrogen Production
T2 - Advances, Challenges, and Opportunities
AU - Faisal, Nadimul Haque
AU - Prathuru, Anil
AU - Ahmed, Rehan
AU - Rajendran, Vinooth
AU - Hossain, Mamdud
AU - Venkatachalapathy, Viswanathan
AU - Katiyar, Nirmal Kumar
AU - Li, Jing
AU - Liu, Yuheng
AU - Cai, Qiong
AU - Horri, Bahman Amini
AU - Thanganadar, Dhinesh
AU - Sodhi, Gurpreet Singh
AU - Patchigolla, Kumar
AU - Fernandez, Carlos
AU - Joshi, Shrikant
AU - Govindarajan, Sivakumar
AU - Kurushina, Victoria
AU - Katikaneni, Sai
AU - Goel, Saurav
N1 - Publisher Copyright:
© 2022 The Authors. ChemNanoMat published by Wiley-VCH GmbH.
PY - 2022/12
Y1 - 2022/12
N2 - Thermal spray coatings have the advantage of providing thick and functional coatings from a range of engineering materials. The associated coating processes provide good control of coating thickness, morphology, microstructure, pore size and porosity, and residual strain in the coatings through selection of suitable process parameters for any coating material of interest. This review consolidates scarce literature on thermally sprayed components which are critical and vital constituents (e. g., catalysts (anode/cathode), solid electrolyte, and transport layer, including corrosion-prone parts such as bipolar plates) of the water splitting electrolysis process for hydrogen production. The research shows that there is a gap in thermally sprayed feedstock material selection strategy as well as in addressing modelling needs that can be crucial to advancing applications exploiting their catalytic and corrosion-resistant properties to split water for hydrogen production. Due to readily scalable production enabled by thermal spray techniques, this manufacturing route bears potential to dominate the sustainable electrolyser technologies in the future. While the well-established thermal spray coating variants may have certain limitations in the manner they are currently practiced, deployment of both conventional and novel thermal spray approaches (suspension, solution, hybrid) is clearly promising for targeted development of electrolysers.
AB - Thermal spray coatings have the advantage of providing thick and functional coatings from a range of engineering materials. The associated coating processes provide good control of coating thickness, morphology, microstructure, pore size and porosity, and residual strain in the coatings through selection of suitable process parameters for any coating material of interest. This review consolidates scarce literature on thermally sprayed components which are critical and vital constituents (e. g., catalysts (anode/cathode), solid electrolyte, and transport layer, including corrosion-prone parts such as bipolar plates) of the water splitting electrolysis process for hydrogen production. The research shows that there is a gap in thermally sprayed feedstock material selection strategy as well as in addressing modelling needs that can be crucial to advancing applications exploiting their catalytic and corrosion-resistant properties to split water for hydrogen production. Due to readily scalable production enabled by thermal spray techniques, this manufacturing route bears potential to dominate the sustainable electrolyser technologies in the future. While the well-established thermal spray coating variants may have certain limitations in the manner they are currently practiced, deployment of both conventional and novel thermal spray approaches (suspension, solution, hybrid) is clearly promising for targeted development of electrolysers.
KW - catalysts
KW - electrolyser
KW - hydrogen production
KW - renewable energy
KW - thermal spray
UR - http://www.scopus.com/inward/record.url?scp=85141637217&partnerID=8YFLogxK
U2 - 10.1002/cnma.202200384
DO - 10.1002/cnma.202200384
M3 - Review article
AN - SCOPUS:85141637217
SN - 2199-692X
VL - 8
JO - ChemNanoMat
JF - ChemNanoMat
IS - 12
M1 - e202200384
ER -
