Achievable boundary conditions in potentiostatic and galvanostatic hydrogen permeation through palladium and nickel foils

Archer, Mary D.; Grant, Neil

doi:10.1098/rspa.1984.0096

Cited by 22 publications

(1 citation statement)

References 21 publications

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“…Galvanostatic hydrogen charging maintains a constant current density at the charging surface, and is commonly considered to represent application of a constant hydrogen flux, J0, at the charging surface. The boundary conditions for solution of Fick's laws therefore become [173]:…”

Section: Galvanostatic Chargingmentioning

confidence: 99%

Hydrogen Embrittlement of Automotive Ultra-High-Strength Steels: Mechanism and Minimisation

Lelliott¹

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Automotive manufacturers are increasingly using ultra-high-strength steels in vehicle components to facilitate mass reduction via downgauging. Unfortunately, as the strength of steels increases, so does susceptibility to ‘hydrogen embrittlement’, a process in which ductility is significantly impaired by ingress of hydrogen. Mechanisms and environmental conditions by which this degradation occurs are not fully understood. In this work, 2 fully-ferritic, 2 fully-martensitic boron, and 2 ferrite-martensite dual-phase, ultra-high-strength steels, were assessed for susceptibility to hydrogen embrittlement via 3 key characteristics: firstly, with particular regard to hydrogen evolution under corrosion conditions, through well-established open circuit potential and potentiodynamic polarisation experiments. Exacerbation of hydrogen evolution through galvanic corrosion of a zinc coating was assessed by scanning vibrating electrode technique (SVET), and an attempt made to quantify increased risk of hydrogen evolution during crevice corrosion through a novel time-lapse photography experiment. Secondly, hydrogen diffusivity was assessed via permeation experiments. Finally, degradation in mechanical properties due to diffusing hydrogen was evaluated through slow strain rate tests (SSRT), whereby susceptibility to embrittlement was equated to reduction in ductility of hydrogen-charged test specimens. The fully-ferritic steels showed the greatest resistance to mechanical degradation, attributed to micro-alloy nano-precipitates within their microstructure acting as ‘traps’, leading to lower diffusivity compared to dual-phase steels of equivalent strength. Indeed, lower diffusivity showed a strong correlation with lower levels of embrittlement across all steels. 1000 MPa dual-phase steel showed the greatest degradation in mechanical properties, with fully-martensitic boron steels also found to be particularly susceptible. 1000 MPa dual-phase steel also showed the largest increase in hydrogen evolution reaction in response to polarisation, thought to result from the inherent potential difference between ferrite and martensite phases. Galvanic corrosion of a damaged zinc coating was found to polarise the exposed steel substrate, triggering sufficient hydrogen evolution to reach critical concentrations for embrittlement.

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Section: Galvanostatic Chargingmentioning

confidence: 99%

Hydrogen Embrittlement of Automotive Ultra-High-Strength Steels: Mechanism and Minimisation

Lelliott¹

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A Combined Numerical–Experimental Approach for the Critical Hydrogen Diffusion Depth in Steel

Vennet

Verbeken

Depover

2023

steel research int.

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Herein, a numerical solution of Fick's second law in one dimension with experimentally determined diffusion coefficients at different constant loads is combined with slow strain rate tensile tests and subsequent fractography on dual-phase steel. From the latter, the depth of the hydrogen embrittled region is determined and correlated to concentration profiles determined by the numerical model. The concentration profiles indicate that incorporating stress dependency of the diffusion coefficient results in different concentration profiles compared to using a constant diffusivity. Additionally, these allow to more accurately determine a critical local hydrogen concentration based on the total diffusible hydrogen concentration at saturation.

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Electrochemical investigations of the autophoretic coating process

Pfeiffer

Schultze

1991

J Appl Electrochem

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Achievable boundary conditions in potentiostatic and galvanostatic hydrogen permeation through palladium and nickel foils

Cited by 22 publications

References 21 publications

Hydrogen Embrittlement of Automotive Ultra-High-Strength Steels: Mechanism and Minimisation

Hydrogen Embrittlement of Automotive Ultra-High-Strength Steels: Mechanism and Minimisation

A Combined Numerical–Experimental Approach for the Critical Hydrogen Diffusion Depth in Steel

Electrochemical investigations of the autophoretic coating process

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