Hydrogen Embrittlement in Fe3%Si, Visited by Nanomechanical Testing and Cohesive Zone Simulation

Afrooz Barnoush; Tarlan Hajilou; Antonio Alvaro; Nousha Kheradmand; Vigdis Olden; Vidar Osen

Hydrogen Embrittlement in Fe3%Si, Visited by Nanomechanical Testing and Cohesive Zone Simulation

Afrooz Barnoush, Tarlan Hajilou, Antonio Alvaro, Nousha Kheradmand, Vigdis Olden, Vidar Osen

Research output: Contribution to conference › Paper › peer-review

Abstract

This work is part of a multi scale computational and experimental approach in which first principle modelling, nanoscale experiments and continuum simulations are combined in order to represent hydrogen induced degradation and cracking. Nanomechanical testing in air and under electrochemical hydrogen charging conditions are carried out on µm sized single crystal cantilevers of Fe3%Si. Finite element simulations of the cantilever beam testing are performed to obtain the cohesive parameters best representing the yield point of the experimental load displacement curves. The cantilevers tested under hydrogen influence show brittle as well as increased plastic behavior as compared to testing in air. Best fit to the experimental results is obtained for traction separation laws that yielded cohesive energies of 10.1 J/m2 for air and 6.8 J/m2 for hydrogen charging conditions.

Original language	English
Publication status	Published - Dec 2016
Externally published	Yes

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@conference{12ffa10c815448f69c33e86c0f5a4e46,

title = "Hydrogen Embrittlement in Fe3%Si, Visited by Nanomechanical Testing and Cohesive Zone Simulation",

abstract = "This work is part of a multi scale computational and experimental approach in which first principle modelling, nanoscale experiments and continuum simulations are combined in order to represent hydrogen induced degradation and cracking. Nanomechanical testing in air and under electrochemical hydrogen charging conditions are carried out on µm sized single crystal cantilevers of Fe3%Si. Finite element simulations of the cantilever beam testing are performed to obtain the cohesive parameters best representing the yield point of the experimental load displacement curves. The cantilevers tested under hydrogen influence show brittle as well as increased plastic behavior as compared to testing in air. Best fit to the experimental results is obtained for traction separation laws that yielded cohesive energies of 10.1 J/m2 for air and 6.8 J/m2 for hydrogen charging conditions.",

author = "Afrooz Barnoush and Tarlan Hajilou and Antonio Alvaro and Nousha Kheradmand and Vigdis Olden and Vidar Osen",

year = "2016",

month = dec,

language = "English",

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TY - CONF

T1 - Hydrogen Embrittlement in Fe3%Si, Visited by Nanomechanical Testing and Cohesive Zone Simulation

AU - Barnoush, Afrooz

AU - Hajilou, Tarlan

AU - Alvaro, Antonio

AU - Kheradmand, Nousha

AU - Olden, Vigdis

AU - Osen, Vidar

PY - 2016/12

Y1 - 2016/12

N2 - This work is part of a multi scale computational and experimental approach in which first principle modelling, nanoscale experiments and continuum simulations are combined in order to represent hydrogen induced degradation and cracking. Nanomechanical testing in air and under electrochemical hydrogen charging conditions are carried out on µm sized single crystal cantilevers of Fe3%Si. Finite element simulations of the cantilever beam testing are performed to obtain the cohesive parameters best representing the yield point of the experimental load displacement curves. The cantilevers tested under hydrogen influence show brittle as well as increased plastic behavior as compared to testing in air. Best fit to the experimental results is obtained for traction separation laws that yielded cohesive energies of 10.1 J/m2 for air and 6.8 J/m2 for hydrogen charging conditions.

AB - This work is part of a multi scale computational and experimental approach in which first principle modelling, nanoscale experiments and continuum simulations are combined in order to represent hydrogen induced degradation and cracking. Nanomechanical testing in air and under electrochemical hydrogen charging conditions are carried out on µm sized single crystal cantilevers of Fe3%Si. Finite element simulations of the cantilever beam testing are performed to obtain the cohesive parameters best representing the yield point of the experimental load displacement curves. The cantilevers tested under hydrogen influence show brittle as well as increased plastic behavior as compared to testing in air. Best fit to the experimental results is obtained for traction separation laws that yielded cohesive energies of 10.1 J/m2 for air and 6.8 J/m2 for hydrogen charging conditions.

M3 - Paper

ER -

Hydrogen Embrittlement in Fe3%Si, Visited by Nanomechanical Testing and Cohesive Zone Simulation

Abstract

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