Modelling of hydrogen reflection on tungsten fuzzy surface in an erosive hydrogen plasma

Abstract: Modelling of the reflection of energetic hydrogen atoms from tungsten fuzz under hydrogen plasma exposure has been performed using the three-dimensional kinetic Monte Carlo program SURO-FUZZ. The simulation results show that the hydrogen reflection coefficient on a porous tungsten fuzzy surface is 50% lower in comparison with a smooth tungsten surface, which shows good agreement with the measurements. The time evolution of the tungsten fuzzy structure has been investigated under energetic hydrogen bombardment.… Show more

“…While, the complicated physical processes involved during W fuzz growth necessitate a lot of time to simulate. Consequently, a constructed fuzzy surface morphology has been subsequently developed as the construction module to save computational resource, which can form porous structure according to a predefined porosity distribution using MC method [18][19][20]. In this work, the construction module in SURO-FUZZ has been momentously improved by adopting a more advanced approach, which is termed the quartet structure generation set (QSGS) [23].…”

“…In this work, the construction module in SURO-FUZZ has been momentously improved by adopting a more advanced approach, which is termed the quartet structure generation set (QSGS) [23]. The QSGS approach allows for more flexible adjustment of the porous structure, in comparison with the previous approach used in SUOR-FUZZ [18][19][20].…”

“…However, numerical simulations of W fuzz growth are fairly time-consuming because of the complex mechanisms involved. For this reason, a fuzzy surface construction module with the predefined porosity has been incorporated into the three-dimensional (3D) kinetic MC code SURO-FUZZ, which has been used to reproduce and interpret the reflection of hydrogen ion in the laboratory device [18,19].…”

Studies on the impacts of the pore size and shape on deuterium retention in tungsten fuzzy nanostructures

“…While, the complicated physical processes involved during W fuzz growth necessitate a lot of time to simulate. Consequently, a constructed fuzzy surface morphology has been subsequently developed as the construction module to save computational resource, which can form porous structure according to a predefined porosity distribution using MC method [18][19][20]. In this work, the construction module in SURO-FUZZ has been momentously improved by adopting a more advanced approach, which is termed the quartet structure generation set (QSGS) [23].…”

“…In this work, the construction module in SURO-FUZZ has been momentously improved by adopting a more advanced approach, which is termed the quartet structure generation set (QSGS) [23]. The QSGS approach allows for more flexible adjustment of the porous structure, in comparison with the previous approach used in SUOR-FUZZ [18][19][20].…”

“…However, numerical simulations of W fuzz growth are fairly time-consuming because of the complex mechanisms involved. For this reason, a fuzzy surface construction module with the predefined porosity has been incorporated into the three-dimensional (3D) kinetic MC code SURO-FUZZ, which has been used to reproduce and interpret the reflection of hydrogen ion in the laboratory device [18,19].…”

Studies on the impacts of the pore size and shape on deuterium retention in tungsten fuzzy nanostructures

An Overview of the Hybrid Illinois Device for Research and Applications Material Analysis Test-stand (HIDRA-MAT)

Modelling of physical sputtering properties during tungsten fuzz growth under various impact energies on NAGDIS-II