High temperature corrosion beneath carbonate melts of aluminide coatings for CSP application

Audigié, Pauline; Encinas Sánchez, V.; Sergio, Rodríguez Catela; Pérez Trujillo, Francisco Javier; Agüero, Alina

Publicación:
High temperature corrosion beneath carbonate melts of aluminide coatings for CSP application

dc.contributor.author	Audigié, Pauline
dc.contributor.author	Encinas Sánchez, V.
dc.contributor.author	Sergio, Rodríguez Catela
dc.contributor.author	Pérez Trujillo, Francisco Javier
dc.contributor.author	Agüero, Alina
dc.contributor.funder	European Commission
dc.date.accessioned	2026-01-21T12:35:04Z
dc.date.available	2026-01-21T12:35:04Z
dc.date.issued	2020-03-20
dc.description	Highlights Corrosion of P91 by molten carbonates at 650 °C takes place at very fast rates. Dynamic conditions lead to higher corrosion degradation of coated and uncoated samples. Non-uniform corrosion takes place on FeAl coated systems. Mn from the substrate reaches the corrosion scale surface on coated and uncoated P91.
dc.description.abstract	Slurry iron-aluminide coatings deposited by spraying on 9 wt% Cr P91 alloy as well as uncoated P91 were exposed isothermally at 650 °C to a ternary molten salt mixture based on a Na, K and Li carbonate eutectic, under static and dynamic conditions. Uncoated P91 evidenced considerable mass gains and extensive spallation in both conditions. Indeed, P91 developed a very thick fast growing multilayered oxide scale which included LiFeO2, LiFe5O8 and (Fe,Cr)3O4. Under dynamic conditions, the metal loss was higher that when the test was carried out statically but this was not reflected in the gravimetric measurements likely due to spallation of the scales in both cases. The coated systems performed better than the uncoated material up to at least 1000 h according to metallographic inspection. However, the aluminide coating showed non-uniform attack and on the corresponding zones, a thick layer likely consisting of LiFeO2 developed over an internal oxidation zone corresponding to all of the coating initial thickness. K was also detected within the internal oxidation zone suggesting that the coating was internally attacked at least by K containing species (Li cannot be detected by EDS). K and perhaps Li seem to diffuse along the grain boundaries of the coating, leading to internal oxidation responsible for the degradation. On the non-degraded zones, the coating maintained the initial microstructure as very low coating/substrate interdiffusion occurred. A 20 wt% average Al content at the surface does not seem to be high enough to sustain a protective oxide.
dc.description.peerreviewed	Peerreview
dc.description.sponsorship	This project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No 686008 (RAISELIFE). We acknowledge its support and we also thank all the members of the Metallic Materials Area at INTA for technical support.
dc.identifier.citation	Solar Energy Materials and Solar Cells 210: 110514
dc.identifier.doi	10.1016/j.solmat.2020.110514
dc.identifier.e-issn	1879-3398
dc.identifier.issn	0927-0248
dc.identifier.other	https://www.sciencedirect.com/science/article/abs/pii/S0927024820301185
dc.identifier.uri	https://hdl.handle.net/20.500.12666/1648
dc.language.iso	eng
dc.publisher	Elsevier
dc.relation	RAISELIFE 686008
dc.relation.isreferencedby	A. Bonk et al. Advanced heat transfer fluids for direct molten salt line-focusing CSP plants Prog. Energy Combust. Sci. (2018) S. Guillot et al. Corrosion effects between molten salts and thermal storage material for concentrated solar power plants Appl. Energy (2012) Y. Grosu et al. The effect of humidity, impurities and initial state on the corrosion of carbon and stainless steels in molten HitecXL salt for CSP application Sol. Energy Mater. Sol. Cell. (2018) G. Garcia-Martin et al. Evaluation of corrosion resistance of A516 Steel in a molten nitrate salt mixture using a pilot plant facility for application in CSP plants Sol. Energy Mater. Sol. Cell. (2017) C.K. Ho Advances in central receivers for concentrating solar applications Sol. Energy (2017) M.T. de Miguel et al. Corrosion resistance of HR3C to a carbonate molten salt for energy storage applications in CSP plants Sol. Energy Mater. Sol. Cell. (2016) R.E. Ciez et al. The cost of lithium is unlikely to upend the price of Li-ion storage systems J. Power Sources (2016) C.S. Turchi et al. Molten salt power towers operating at 600-650 degrees C: salt selection and cost benefits Sol. Energy (2018) V. Encinas-Sanchez et al. Corrosion resistance of Cr/Ni alloy to a molten carbonate salt at various temperatures for the next generation high-temperature CSP plants Sol. Energy (2018) M. Sarvghad et al. Corrosion of steel alloys in eutectic NaCl + Na2CO3 at 700°C and Li2CO3 + K2CO3 + Na2CO3 at 450°C for thermal energy storage Sol. Energy Mater. Sol. Cell. (2017) M. Sarvghad et al. Corrosion of stainless steel 316 in eutectic molten salts for thermal energy storage Sol. Energy (2018) S.P. Sah et al. Corrosion behaviour of austenitic stainless steels in carbonate melt at 923 K under controlled CO2-O2 environment Corrosion Sci. (2018) M. Sarvghad et al. Corrosion of Inconel 601 in molten salts for thermal energy storage Sol. Energy Mater. Sol. Cell. (2017) F.J. Perez et al. Hot corrosion study of coated separator plates of molten carbonate fuel cells by slurry aluminides Surf. Coating. Technol. (2002) A. Agüero et al. Thermal spray coatings for molten carbonate fuel cells separator plates Surf. Coating. Technol. (2001) J.C. Gomez-Vidal et al. Corrosion evaluation of alloys and MCrAlX coatings in molten carbonates for thermal solar applications Sol. Energy Mater. Sol. Cell. (2016) A. Soleimani Dorcheh et al. Slurry Aluminizing: a solution for molten nitrate salt corrosion in concentrated solar power plants Sol. Energy Mater. Sol. Cell. (2016) C.S. Ni et al. Evaluation of corrosion resistance of aluminium coating with and without annealing against molten carbonate using electrochemical impedance spectroscopy J. Power Sources (2014) J.G. Gonzalez-Rodriguez et al. Effect of heat treatment and chemical composition on the corrosion behavior of FeAl intermetallics in molten (Li + K) carbonate J. Power Sources (2007) P. Audigie et al. High temperature molten salt corrosion behavior of aluminide and nickel-aluminide coatings for heat storage in concentrated solar power plants Surf. Coating. Technol. (2018) A. Aguero et al. Biomass corrosion behavior of steels and coatings in contact with KCl/K2SO4 at 550°C under an oxy-fuel combustion atmosphere: a screening laboratory test Surf. Coating. Technol. (2018) A. Agüero et al. Diffusion stable aluminide coatings; behavior under steam and oxy-fuel fire-side corrosions Surf. Coating. Technol. (2018) A. Kruizenga et al. Corrosion of iron stainless steels in molten nitrate salt M. Spiegel et al. Corrosion of iron base alloys and high alloy steels in the Li2CO3-K2CO3 eutectic mixture Corrosion Sci. (1997) There are more references available in the full text version of this article.
dc.rights.accessRights	info:eu-repo/semantics/restrictedAccess
dc.rights.license	© 2020 Elsevier B.V. All rights reserved.
dc.title	High temperature corrosion beneath carbonate melts of aluminide coatings for CSP application
dc.type	info:eu-repo/semantics/article
dc.type.coar	http://purl.org/coar/resource_type/c_2df8fbb1
dc.type.hasVersion	info:eu-repo/semantics/publishedVersion
dspace.entity.type	Publication
oaire.awardNumber	686008
oaire.awardTitle	RAISELIFE 686008
oaire.awardURI	https://digitalpro.inta.es/handle/123456789/1445
relation.isAuthorOfPublication	686217e1-1771-46e8-a536-1fd94a7bdec8
relation.isAuthorOfPublication	a6be277e-0b0c-4412-802d-b754ed778a1a
relation.isAuthorOfPublication	e9bb07d6-3bc5-49b1-8063-44e63da908c2
relation.isAuthorOfPublication.latestForDiscovery	686217e1-1771-46e8-a536-1fd94a7bdec8
relation.isProjectOfPublication	95dd8efd-179d-49a3-b2ef-4a3fbb1260c2
relation.isProjectOfPublication.latestForDiscovery	95dd8efd-179d-49a3-b2ef-4a3fbb1260c2