Dislocation-based approaches for simulating plastic deformation in BCC metals under high-rate loading
Abstract not provided.
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Jump to search filtersCombining Full-Field Measurements and Inverse Techniques for Smart Material Testing
Abstract not provided.
Ductile Void Nucleation in Pure BCC Metals under Quasi-static Loading
Abstract not provided.
High Throughput Stochastic Tensile Performance of Additively Manufactured Stainless Steels
Abstract not provided.
Digital Image Correlation (DIC) ? The development and use of full-field optical measurements
Abstract not provided.
Qualifying Mechanical Properties of Additive Manufactured Metals
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Feedstock effects on defects in AlSi10Mg
Abstract not provided.
Porosity determination in powder bed aluminum alloy
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Mechanisms for Ductile Rupture - FY16 ESC Progress Report
Ductile rupture in metals is generally a multi-step process of void nucleation, growth, and coalescence. Particle decohesion and particle fracture are generally invoked as the primary microstructural mechanisms for room-temperature void nucleation. However, because high-purity materials also fail by void nucleation and coalescence, other microstructural features must also act as sites for void nucleation. Early studies of void initiation in high-purity materials, which included post-mortem fracture surface characterization using scanning electron microscopy (SEM) and high-voltage electron microscopy (HVEM) and in-situ HVEM observations of fracture, established the presence of dislocation cell walls as void initiation sites in high-purity materials. Direct experimental evidence for this contention was obtained during in-situ HVEM tensile tests of Be single crystals. Voids between 0.2 and 1 μm long appeared suddenly along dislocation cell walls during tensile straining. However, subsequent attempts to replicate these results in other materials, particularly α -Fe single crystals, were unsuccessful because of the small size of the dislocation cells, and these remain the only published in-situ HVEM observations of void nucleation at dislocation cell walls in the absence of a growing macrocrack. Despite this challenge, other approaches to studying void nucleation in high-purity metals also indicate that dislocation cell walls are nucleation sites for voids.
Fracture Mechanics Seminar Series Lecture 4: Fracture Resistant Design
Abstract not provided.
Efficient structural reliability including the effects of crystallographic texture on engineering-scale performance
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Damage Evolution Study and Volumetric Deformation Measurement of Sylgard
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Defect characterization in powder bed AM aluminum
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Microstructural and Mechanical Evaluation of Stainless Steel to Fe-Co-V Soft Magnetic Alloy Friction Welds
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Micromechanics of Damage in Glass Microballoon Filled Syntactic Foams
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Identifying and Validating Material Models with Non-Unique Parameter Sets
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Fracture Mechanics Seminar Series Lecture 2: Experimental Fracture Mechanics
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Mechanical Properties and Trends in Additively Manufactured Aluminum
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Identification of critical defects in powder bed additively manufactured metals
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Combining Full-Field Measurements and Inverse Techniques for Smart Material Testing
Abstract not provided.
Multiple Testing Techniques and Multiple Conclusions in AM Metals
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Thermal Characterization of AlSi10Mg Alloy Fabricated by Selective Laser Melting
Abstract not provided.
Combining Full-Field Measurements and Inverse Techniques for Smart Material Testing
Abstract not provided.
Quantitative Grain-Scale Validations of a BCC Crystal Plasticity Model using Single and Polycrystalline Tantalum
Abstract not provided.
Identification of Viscoplastic Material Properties using the Virtual Fields Method
Abstract not provided.
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