Investigation of Microscale Damage Evolution in High-Strength Al Alloy
Abstract not provided.
Publications
Investigation of Microscale Damage Evolution in High Strength A1 Alloy
Abstract not provided.
A Study of Void Evolution Mechanism in Aluminum using X-Ray Tomography
Proposed for publication in Experimental Mechanics.
Abstract not provided.
Modeling fluid flow in deformation bands with stabilized localization mixed finite elements
Abstract not provided.
The relationship between crack-tip strain and subcritical cracking thresholds for steels in high-pressure hydrogen gas
Proposed for publication in Metallurgical and Materials Transactions A.
Abstract not provided.
A Study of Void Evolution Mechanism in Aluminum Alloy using micro-XCT
Abstract not provided.
Characterization and Modeling via 3D Reconstructions of Laser Welds in Stainless Steel
Abstract not provided.
A Variational Projection Operator for Mapping of Internal Variables
Abstract not provided.
Anisotropic Damage Evolution in Aluminum Alloy 7075-T7351
Abstract not provided.
Characterization and Mechanical Response in Laser-Welds of 304L Stainless Steel
Abstract not provided.
A Variational Pro jection Operator for Mapping of Internal Variables
Proposed for publication in International Journal for Numerical Methods in Engineering.
Abstract not provided.
On the Numerical Approaches to Material Bifurcation
Abstract not provided.
Strongly Coupled Thermo-Elastoplasticity
Abstract not provided.
Anisotropic Failure and Damage Evolution of A High Strength Aluminum Alloy
Abstract not provided.
Modeling Techniques for Localization and Failure
Abstract not provided.
hydrogen-assisted fracture of 12Cr-6Ni-9Mn stable austenitic stainless steel
Abstract not provided.
Ductile failure X-prize
Fracture or tearing of ductile metals is a pervasive engineering concern, yet accurate prediction of the critical conditions of fracture remains elusive. Sandia National Laboratories has been developing and implementing several new modeling methodologies to address problems in fracture, including both new physical models and new numerical schemes. The present study provides a double-blind quantitative assessment of several computational capabilities including tearing parameters embedded in a conventional finite element code, localization elements, extended finite elements (XFEM), and peridynamics. For this assessment, each of four teams reported blind predictions for three challenge problems spanning crack initiation and crack propagation. After predictions had been reported, the predictions were compared to experimentally observed behavior. The metal alloys for these three problems were aluminum alloy 2024-T3 and precipitation hardened stainless steel PH13-8Mo H950. The predictive accuracies of the various methods are demonstrated, and the potential sources of error are discussed.
Towards Coupling Plasticity and Gradient Damage
Abstract not provided.
Varational Nonlocal Regularization in Finite-Deformation Inelasticity
Abstract not provided.
Variational Nonlocal Regularization in Finite-Deformation Inelasticity
Abstract not provided.
Study Damage Evolution in High Strength Aluminum using X-Ray Tomography
Abstract not provided.
Predicting Fracture in Micron-Scale Polycrystalline Silicon MEMS Structures
Abstract not provided.
Void Kinematics and Tomography for Anisotropic Damage
Abstract not provided.
Study of Damage Evolution in High Strength Al Alloy using X-Ray Tomography
Abstract not provided.
Voids Growth and Coalescence Study of Al 7075-T7351 using X-Ray Tomography
Abstract not provided.
Results 101–125 of 137