The 9th International Conference on Multiscale Materials Modeling

Presentation information

Symposium

I. Multiscale Modeling of Grain Boundary Dynamics, Grain Growth and Polycrystal Plasticity

[SY-I4] Symposium I-4

Tue. Oct 30, 2018 11:15 AM - 12:30 PM Room7

Chairs: Shen J Dillon(University of Illinois, USA), Daniel Pino Munoz(Mines ParisTech / PSL Research University, France)

[SY-I4] Atomistic modeling of helium segregation to grain boundaries in tungsten and its effect on de-cohesion

Invited

Enrique Martinez Saez1, Blas Pedro Uberuaga1, Brian D Wirth2,3 (1.Material Science and Technology Division, MST-8,Los Alamos National Laboratory, Los Alamos, 87545 NM, USA, United States of America, 2.Department of Nuclear Engineering, University of Tennessee, Knoxville, TN 37996, United States of America, United States of America, 3.Oak Ridge National Laboratory, PO Box 2008, MS-6003, Oak Ridge, TN 37831, United States of America, United States of America)

Due to their low sputtering yield, low intrinsic tritium retention, high melting point, and high thermal conductivity, W and W alloys are promising candidates for the divertor region in a magnetic fusion device. Transmutation reactions under neutron irradiation lead to the formation of He and H particles that potentially degrade material performance and might lead to failure. High He fluxes ultimately lead to the formation and bursting of bubbles that induce swelling, a strong decrease in toughness, and a nanoscale microstructure that potentially degrades the plasma. Understanding the behavior of He in polycrystalline W is thus of significant importance as one avenue for controlling the material properties under operating conditions. In this work we study the interaction of both substitutional and interstitial He atoms with various grain boundaries in pure W and the effect of the He presence on the system response to external loading. We observe that He segregates to all the interfaces tested and decreases the cohesion of the system at the grain boundary. Upon tension normal to the interface, the presence of He significantly decreases the yield stress, which depends considerably on the bubble pressure. Increasing pressure reduces cohesion, as expected. More complex stress states result in more convoluted behavior, with He hindering grain boundary sliding upon simple shear.