TY - JOUR
T1 - Modelling Hydrogen Embrittlement using Density Functional Theory
T2 - A theoretical approach to understanding environmentally assisted cracking in 7xxx series aluminium alloys
AU - Wilson, Benjamin
AU - Robson, Joseph
AU - Race, Christopher
PY - 2020/11/5
Y1 - 2020/11/5
N2 - The effects of H segregation to a Σ11 symmetric tilt Al grain boundary are investigated using atomistic simulations, as part of a wider study on cracking in 7xxx series alloys. Density functional theory based simulations of uniaxial straining of grain boundaries containing 11 different concentrations of H were performed under the cohesive zone fracture mechanics framework. The theoretical strength of grain boundaries is shown to be supressed by H segregation, and the cause of this is attributed to the prevention of the formation of Al ligaments across grain boundaries. Segregated concentrations of relevant alloying elements (Zn, Mg, and Cu) show minimal impact on the H embrittlement process investigated, namely H enhanced decohesion (HEDE). Further modelling, of H transport and grain boundary precipitates, is required to confirm the validity of the HEDE mechanism in the case of 7xxx alloys.
AB - The effects of H segregation to a Σ11 symmetric tilt Al grain boundary are investigated using atomistic simulations, as part of a wider study on cracking in 7xxx series alloys. Density functional theory based simulations of uniaxial straining of grain boundaries containing 11 different concentrations of H were performed under the cohesive zone fracture mechanics framework. The theoretical strength of grain boundaries is shown to be supressed by H segregation, and the cause of this is attributed to the prevention of the formation of Al ligaments across grain boundaries. Segregated concentrations of relevant alloying elements (Zn, Mg, and Cu) show minimal impact on the H embrittlement process investigated, namely H enhanced decohesion (HEDE). Further modelling, of H transport and grain boundary precipitates, is required to confirm the validity of the HEDE mechanism in the case of 7xxx alloys.
UR - http://dx.doi.org/10.1051/matecconf/202032604006
U2 - 10.1051/matecconf/202032604006
DO - 10.1051/matecconf/202032604006
M3 - Conference article
SN - 2261-236X
VL - 326
JO - MATEC Web of Conferences
JF - MATEC Web of Conferences
M1 - 04006
ER -