Tensile stress-driven cracking of W fuzz over W crystal under fusion-relevant He ion irradiations
出版年份 2020 全文链接
标题
Tensile stress-driven cracking of W fuzz over W crystal under fusion-relevant He ion irradiations
作者
关键词
-
出版物
NUCLEAR FUSION
Volume 60, Issue 4, Pages 046011
出版商
IOP Publishing
发表日期
2020-01-31
DOI
10.1088/1741-4326/ab71bb
参考文献
相关参考文献
注意:仅列出部分参考文献,下载原文获取全部文献信息。- Systematic study of He induced nano-fiber formation of W and other period 6 transition metals
- (2018) Y. Ueda et al. JOURNAL OF NUCLEAR MATERIALS
- Motion of W and He atoms during formation of W fuzz
- (2018) R.P. Doerner et al. NUCLEAR FUSION
- The influence of plasma-surface interaction on the performance of tungsten at the ITER divertor vertical targets
- (2018) G De Temmerman et al. PLASMA PHYSICS AND CONTROLLED FUSION
- He-ion induced surface morphology change and nanofuzz growth on hot tungsten surfaces
- (2018) F W Meyer JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS
- Overview of fuel inventory in JET with the ITER-like wall
- (2017) A. Widdowson et al. NUCLEAR FUSION
- Experimental mechanistic investigation of the nanostructuring of tungsten with low energy helium plasmas
- (2016) P. Fiflis et al. JOURNAL OF NUCLEAR MATERIALS
- High-flux He + irradiation effects on surface damages of tungsten under ITER relevant conditions
- (2016) Lu Liu et al. JOURNAL OF NUCLEAR MATERIALS
- Magnetic-confinement fusion
- (2016) J. Ongena et al. Nature Physics
- A molecular dynamics study on bubble growth in tungsten under helium irradiation
- (2015) Ryo Kobayashi et al. JOURNAL OF NUCLEAR MATERIALS
- Tungsten ‘fuzz’ growth re-examined: the dependence on ion fluence in non-erosive and erosive helium plasma
- (2015) T.J. Petty et al. NUCLEAR FUSION
- Competing Kinetics and He Bubble Morphology in W
- (2015) Luis Sandoval et al. PHYSICAL REVIEW LETTERS
- Nanostructured fuzz growth on tungsten under low-energy and high-flux He irradiation
- (2015) Qi Yang et al. Scientific Reports
- Helium defects interactions and mechanism of helium bubble growth in tungsten: A molecular dynamics simulation
- (2014) Xiao-Chun Li et al. JOURNAL OF NUCLEAR MATERIALS
- First principles study of helium trapping by solute elements in tungsten
- (2014) Xuebang Wu et al. JOURNAL OF NUCLEAR MATERIALS
- Molecular dynamics simulations of cumulative helium bombardments on tungsten surfaces
- (2014) Min Li et al. NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION B-BEAM INTERACTIONS WITH MATERIALS AND ATOMS
- Helium concentration in tungsten nano-tendril surface morphology using Elastic Recoil Detection
- (2013) K.B. Woller et al. JOURNAL OF NUCLEAR MATERIALS
- Numerical simulation of the bubble growth due to hydrogen isotopes inventory processes in plasma-irradiated tungsten
- (2013) Chaofeng Sang et al. JOURNAL OF NUCLEAR MATERIALS
- Comparison of tungsten nano-tendrils grown in Alcator C-Mod and linear plasma devices
- (2013) G.M. Wright et al. JOURNAL OF NUCLEAR MATERIALS
- Nanostructuring of molybdenum and tungsten surfaces by low-energy helium ions
- (2012) Gregory De Temmerman et al. JOURNAL OF VACUUM SCIENCE & TECHNOLOGY A
- Tungsten nano-tendril growth in the Alcator C-Mod divertor
- (2012) G.M. Wright et al. NUCLEAR FUSION
- Model of fuzz formation on a tungsten surface
- (2012) Yu. V. Martynenko et al. PLASMA PHYSICS REPORTS
- An equilibrium model for tungsten fuzz in an eroding plasma environment
- (2011) R.P. Doerner et al. NUCLEAR FUSION
- Viscoelastic model of tungsten ‘fuzz’ growth
- (2011) S I Krasheninnikov PHYSICA SCRIPTA
- Formation of helium induced nanostructure ‘fuzz’ on various tungsten grades
- (2010) M.J. Baldwin et al. JOURNAL OF NUCLEAR MATERIALS
- Exposure of tungsten nano-structure to TEXTOR edge plasma
- (2010) Y. Ueda et al. JOURNAL OF NUCLEAR MATERIALS
- Helium induced nanoscopic morphology on tungsten under fusion relevant plasma conditions
- (2008) M.J. Baldwin et al. NUCLEAR FUSION
Discover Peeref hubs
Discuss science. Find collaborators. Network.
Join a conversationPublish scientific posters with Peeref
Peeref publishes scientific posters from all research disciplines. Our Diamond Open Access policy means free access to content and no publication fees for authors.
Learn More