Fates of Hydrogen During Alumina Growth Below Yttria Nodules in FeCrAl(RE) at Low Partial Pressures of Water
Journal article, 2017

Oxidation of FeCrAl(Re), when exposed to similar to 35 ppm of water as sole supply of oxygen in predominantly nitrogen atmosphere, has two characteristic signatures. One is the internal nitridation owing to chromia nodules acting windows toward nitrogen permeation locally short-circuiting the protective alpha-Al2O3 scale. The second remarkable feature is the growth of thick, apparently defect-rich alumina scale under yttria-rich nodules. Hence, one part of the present study comprises exploratory DFT calculations to discriminate between the impacts of chromia and yttria viz. nitrogen permeation. The second part concerns boundary conditions for apparent rapid growth of alumina under yttria nodules. Yttria-associated surface energy stabilization of defect-rich alumina in presence of water was argued to involve hydrolysis-driven hydroxylation of said interface. Subsequent inward growth of the alumina scale was associated with outward diffusion of oxygen vacancies to be accommodated by the remaining proton producing a hydride ion upon surfacing at yttria-decorated alumina interfaces. The latter comprises the cathode process in a quasi-Wagnerian context. Two fates were discussed for this surface ion. One has H--H+ recombination to form H-2 at the interface in conjunction with OH- accommodation upon hydration, while the second allows hydrogen to be incorporated at V-O sites in hydroxylated grain boundaries of the growing alumina scale. The latter was taken to explain the experimentally observed rapid oxide growth under yttria-rich nodules. Space charge due to proton reduction was proposed to cause transient inward cationic drag.

Hydrogen evolution

Low partial pressure of oxygen

High temperature alloy

Oxygen vacancy

FeCrAl

Oxide growth

Confinement effect

Hydride in oxide

H-2 reducing conditions

Yttria

Alumina

Defects

N-2 atmosphere

Oxidation by water

Author

Vedad Babic

Chalmers, Chemistry and Chemical Engineering, Energy and Material

Christine Geers

Chalmers, Chemistry and Chemical Engineering, Energy and Material

Bo Jönsson

Chalmers, Chemistry and Chemical Engineering, Energy and Material

Itai Panas

Chalmers, Chemistry and Chemical Engineering, Energy and Material

Electrocatalysis

1868-2529 (ISSN) 1868-5994 (eISSN)

Vol. 8 6 565-576

Subject Categories

Inorganic Chemistry

Physical Chemistry

Materials Chemistry

DOI

10.1007/s12678-017-0368-8

More information

Latest update

10/24/2022