Quantification of hydrogen trapping in multiphase steels: part II – effect of austenite morphology
Quantification of hydrogen trapping in multiphase steels: part II – effect of austenite morphology
We tackle the role of austenite in multiphase steels on hydrogen diffusion systematically for the first time, considering a range of factors such as morphology, interface kinetics and the additional effect of point traps using both experiments and modelling. This follows the findings from part I where we showed that austenite cannot be parametrised and modelled as point traps under the assumption of local equilibrium, unlike grain boundaries and dislocations. To solve this, we introduce a 2D hydrogen diffusion model accounting for the difference in diffusivities and solubilities between the phases. We first revisit the as-quenched martensite permeation results from part I and show that the extremely low H diffusivity there can be partly explained with the new description of austenite but is partly likely due to quench vacancies. We then also look at the H absorption and desorption rates in a duplex steel as a case study using a combination of simulations and experiments. The rates are shown to depend heavily on austenite morphology and the kinetics of H transition from ferrite to austenite and that an energy barrier is likely associated to this transition. We show that H diffusion through the ferrite matrix and austenite islands proceeds at similar rates and the assumption of negligible concentration gradients in ferrite occasionally applied in the literature is a poor approximation. This approach is also applicable to other austenite-containing steels as well as other multiphase alloys.
Austenite, Duplex stainless steel, Hydrogen desorption, Hydrogen diffusion, Hydrogen permeation, Interface diffusion
253-268
Turk, Andrej
66ab5921-4c1e-45dc-be21-abfb78f6977b
Pu, Shengda D.
74b15be4-1a22-46ff-80ca-3fc674de1dd3
Bombač, David
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Rivera-Díaz-del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Galindo-Nava, Enrique I.
55a2bf00-0903-414e-8ab6-e26d143a9af3
30 July 2020
Turk, Andrej
66ab5921-4c1e-45dc-be21-abfb78f6977b
Pu, Shengda D.
74b15be4-1a22-46ff-80ca-3fc674de1dd3
Bombač, David
0a905647-d3ad-4448-a662-7f6d177e7cbd
Rivera-Díaz-del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Galindo-Nava, Enrique I.
55a2bf00-0903-414e-8ab6-e26d143a9af3
Turk, Andrej, Pu, Shengda D., Bombač, David, Rivera-Díaz-del-Castillo, Pedro E.J. and Galindo-Nava, Enrique I.
(2020)
Quantification of hydrogen trapping in multiphase steels: part II – effect of austenite morphology.
Acta Materialia, 197, .
(doi:10.1016/j.actamat.2020.07.039).
Abstract
We tackle the role of austenite in multiphase steels on hydrogen diffusion systematically for the first time, considering a range of factors such as morphology, interface kinetics and the additional effect of point traps using both experiments and modelling. This follows the findings from part I where we showed that austenite cannot be parametrised and modelled as point traps under the assumption of local equilibrium, unlike grain boundaries and dislocations. To solve this, we introduce a 2D hydrogen diffusion model accounting for the difference in diffusivities and solubilities between the phases. We first revisit the as-quenched martensite permeation results from part I and show that the extremely low H diffusivity there can be partly explained with the new description of austenite but is partly likely due to quench vacancies. We then also look at the H absorption and desorption rates in a duplex steel as a case study using a combination of simulations and experiments. The rates are shown to depend heavily on austenite morphology and the kinetics of H transition from ferrite to austenite and that an energy barrier is likely associated to this transition. We show that H diffusion through the ferrite matrix and austenite islands proceeds at similar rates and the assumption of negligible concentration gradients in ferrite occasionally applied in the literature is a poor approximation. This approach is also applicable to other austenite-containing steels as well as other multiphase alloys.
Text
1-s2.0-S1359645420305462-main
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Accepted/In Press date: 14 July 2020
e-pub ahead of print date: 17 July 2020
Published date: 30 July 2020
Keywords:
Austenite, Duplex stainless steel, Hydrogen desorption, Hydrogen diffusion, Hydrogen permeation, Interface diffusion
Identifiers
Local EPrints ID: 492069
URI: http://eprints.soton.ac.uk/id/eprint/492069
ISSN: 1359-6454
PURE UUID: f99045f6-69df-4f48-a6ba-670a3e31ee1d
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Date deposited: 15 Jul 2024 16:53
Last modified: 16 Jul 2024 02:05
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Contributors
Author:
Andrej Turk
Author:
Shengda D. Pu
Author:
David Bombač
Author:
Pedro E.J. Rivera-Díaz-del-Castillo
Author:
Enrique I. Galindo-Nava
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