Simpson et al., 2017 - Google Patents
Hydrogen in steels: discussionSimpson et al., 2017
View HTML- Document ID
- 16332163446816136529
- Author
- Simpson E
- Patel M
- Publication year
- Publication venue
- Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences
External Links
Snippet
Hydrogen in steels: discussion | Philosophical Transactions of the Royal Society A:
Mathematical, Physical and Engineering Sciences logo Skip main navigationJournal menuClose
Drawer MenuOpen Drawer Menu Home All Journals Biographical Memoirs Biology Letters …
- 239000001257 hydrogen 0 title abstract description 129
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Dear et al. | Mechanisms of hydrogen embrittlement in steels: discussion | |
| Yu et al. | Hydrogen embrittlement as a conspicuous material challenge─ comprehensive review and future directions | |
| Liu et al. | A critical review of the influence of hydrogen on the mechanical properties of medium-strength steels | |
| Jemblie et al. | A review of cohesive zone modelling as an approach for numerically assessing hydrogen embrittlement of steel structures | |
| McEniry et al. | Ab initio simulation of hydrogen-induced decohesion in cementite-containing microstructures | |
| Solheim et al. | The role of retained austenite in hydrogen embrittlement of supermartensitic stainless steel | |
| Doshida et al. | Hydrogen-enhanced lattice defect formation and hydrogen embrittlement of cyclically prestressed tempered martensitic steel | |
| Takeuchi et al. | Estimation of cumulative deformation capacity of buckling restrained braces | |
| Alexander Stopher et al. | Hydrogen embrittlement in bearing steels | |
| Lai et al. | The fatigue limit of bearing steels–Part I: A pragmatic approach to predict very high cycle fatigue strength | |
| Al-Abbasi et al. | Characterizing DP-steels using micromechanical modeling of cells | |
| Koyama et al. | Hydrogen desorption and cracking associated with martensitic transformation in Fe-Cr-Ni-Based austenitic steels with different carbon contents | |
| Mente et al. | Modeling of hydrogen distributionin a duplex stainless steel | |
| Warhadpande et al. | Microstructural alterations in bearing steels under rolling contact fatigue: part 2—diffusion-based modeling approach | |
| Jackson et al. | Effect of low temperature on hydrogen-assisted crack propagation in 304L/308L austenitic stainless steel fusion welds | |
| Saida et al. | Prediction of solidification cracking in laser welds of type 310 stainless steels | |
| Sasaki et al. | Effects of hydrogen-altered yielding and work hardening on plastic-zone evolution: A finite-element analysis | |
| Tao et al. | Modeling of hydrogen diffusion in duplex stainless steel based on microstructure using finite element method | |
| Yu et al. | Simulating hydrogen in fcc materials with discrete dislocation plasticity | |
| Simpson et al. | Hydrogen in steels: discussion | |
| Sanchez et al. | Diffusion and trapping of hydrogen in carbon steel at different temperatures | |
| Chen et al. | Studying crack propagation along symmetric tilt grain boundary with H segregation in Ni by MD simulation | |
| Ramazani et al. | Characterization and Modeling of Failure Initiation in Bainite‐Aided DP Steel | |
| Arroyo et al. | Rate effects on the estimation of fracture toughness by small punch tests in hydrogen embrittlement | |
| Motoyashiki et al. | Investigation of small crack behaviour under cyclic loading in a dual phase steel with an FIB tomography technique |