Get the latest information on how to extend the design life of structures and accurately predict both the fundamental material behavior and structural response under a wide range of load conditions.
Nine peer-reviewed papers cover:
Ferritic Steelsaddresses fracture in the transition regime, on the upper shelf, and in the creep range. This section also examines the Gurson and Weibull models to predict fracture performance and account for constraint loss.
Electronic Materialsdiscusses the application of the Weibull models used extensively for steel fracture to assess the interfacial fracture of electronic components. These models predict well conditions similar to the calibration dataset.
Computational Techniquescovers advanced computational and experimental techniques to develop constitutive models for composite and shape memory materials.
Transition Toughness Modeling of Steels Since RKR
Kirk M., Natishan M., Wagenhofer M.
Transferability Properties of Local Approach Modeling in the Ductile to Brittle Transition Region
Laukkanen A., Nevasmaa P., Tähtinen S., Wallin K.
A Physics-Based Predictive Model for Fracture Toughness Behavior
Natishan M., Rosinski S., Wagenhofer M.
On the Identification of Critical Damage Mechanisms Parameters to Predict the Behavior of Charpy Specimens on the Upper Shelf
Forget P., Marini B., Poussard C., Sainte Catherine C.
Interface Strength Evaluation of LSI Devices Using the Weibull Stress
Minami F., Nakamura T., Takahara W.
Computational Estimation of Multiaxial Yield Surface Using Microyield Percolation Analysis
Dyka C., Everett R., Geltmacher A., Matic P.
Image-Based Characterization and Finite Element Analysis of Porous SMA Behavior
DeGiorgi V., Everett R., Qidwai M.
Paper ID: STP1429-EB