Reprint
Computational Methods for Fracture
Edited by
October 2019
404 pages
- ISBN978-3-03921-686-4 (Paperback)
- ISBN978-3-03921-687-1 (PDF)
This is a Reprint of the Special Issue Computational Methods for Fracture that was published in
Biology & Life Sciences
Chemistry & Materials Science
Computer Science & Mathematics
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary
Format
- Paperback
License and Copyright
© 2019 by the authors; CC BY-NC-ND license
Keywords
plate; FSDT; HSDT; Mindlin; incompatible approximation; fracture; screened-Poisson model; gradient-enhanced model; damage-plasticity model; implicit gradient-enhancement; rock; shear failure; elastoplastic behavior; extended scaled boundary finite element method (X-SBFEM); stress intensity factors; fracture process zone (FPZ); thermomechanical analysis; moderate fire; finite element simulations; metallic glass matrix composite; finite element analysis; shear band; microstructure; ductility; peridynamics; fatigue; rolling contact; damage; rail squats; cracks; steel reinforced concrete frame; reinforced concrete core tube; progressive collapse analysis; loss of key components; self-healing; damage-healing mechanics; super healing; anisotropic; brittle material; Brittle Fracture; cell-based smoothed-finite element method (CS-FEM); Phase-field model; ABAQUS UEL; the Xulong arch dam; yielding region; cracking risk; overall stability; dam stress zones; concrete creep; prestressing stress; compressive stress; FE analysis; force transfer; grouting; fracture network modeling; numerical simulation; fluid–structure interaction; bulk damage; brittle fracture; rock fracture; random fracture; Mohr-Coulomb; Discontinuous Galerkin; EPB shield machine; conditioned sandy pebble; particle element model; parameters calibration; geometric phase; photonic orbital angular momentum; topological insulator; topological photonic crystal; fatigue crack growth; surface crack; crack shape change; three-parameter model; LEFM; XFEM/GFEM; SBFEM; phase field; n/a