Size effects on the thermal conductivity of silicon-germanium alloy thin films
Proposed for publication in Physical Review Letters.
Abstract not provided.
Publications
Size Effects on the Properties of High Z Scintillator Materials
Abstract not provided.
Precession Electron Microscopy of High-Energy Heavy Ion Irradiated Nanocrystalline Nickel
Abstract not provided.
Rapid First-order Screening and Detailed In situ Microstructural Characterization of Advanced Cladding Materials
Abstract not provided.
Investigating Materials for Nuclear Related Industries at the Nanoscale
The Development of In situ TEM techniques at Sandia's New Ion Beam Laboratory
Abstract not provided.
Understanding Abnormal Grain Growth in Nanograined Nickel through the Combination of in situ TEM and Precession Microscopy
Abstract not provided.
Ion Beam Modification of Nanomaterials vis in situ Ion Irradiation TEM
Abstract not provided.
Sandia?s New Ion Beam Laboratory and Her Capabilities
Abstract not provided.
Connecting structure and function in MOF-based luminescence: Rational design of novel materials for chemical sensing and radiation detection
Abstract not provided.
Application of in-situ ion irradiation TEM and 4D tomography to advanced scintillator materials
Abstract not provided.
Effects of He Implantation on Tensile Properties of Cu/Fe Nano-pillars
Abstract not provided.
Microstructural Evolution of Nanocrystalline Nickel Thin Films due to High-Energy Heavy-Ion Irradiation
Abstract not provided.
Structural Stability of High Z-Nanoparticle Scintillators
Abstract not provided.
In-Situ Ion Irradiation and Tomography of Gold Nanoparticles
Abstract not provided.
Hydride Formation in Cladding materials Studied via In-Situ Environmental Heating Transmission Electron Microscopy
Abstract not provided.
Progress Towards In Situ TEM of Biofouling
Abstract not provided.
Diffusion Couple Approach for Exploring Refractory Metals Additons to Structural Steels
Abstract not provided.
Nanoindentation and TEM Characterization of Ion Irridiated 316L Stainless Steels
Energy Technology 2012: Carbon Dioxide Management and Other Technologies
Understanding the effects of extensive radiation damage in structural metals provides necessary insight for predicting the performance of those metals considered for application in the extreme radiation environment. Predicting mechanical performance after long term radiation exposure is of great importance to extending the life of current nuclear reactors and for developing future materials for the next generation of reactors. A combination of finite element modeling, nanoindentation, and TEM characterization were used to rapidly determine the microstructure and mechanical properties influences of ion irradiation on a standard 316L stainless steel sample. The results of this study found that ion irradiation and small scale mechanical property testing can be used to characterize extensive levels of radiation damage structure, only when significant consideration is given to ion irradiation depth, surface roughness and polishing condition, the irradiation temperature, and.many other experimental parameters. © 2012 The Minerals, Metals, & Materials Society. All rights reserved.
Ion beam induced luminescence and in situ ion irradiation TEM of advanced scintillators
Abstract not provided.
Crystal Growth and Scintillation Properties of Cs2NaGdBr6:Ce3+
Abstract not provided.
A New TEM Imaging Technique for Liposomes
Abstract not provided.
Spectral- and Pulse-Shape Discrimination in Triplet-Harvesting Plastic Scintillators
IEEE Transactions on Nuclear Science
Abstract not provided.
Investigating Radiation at the Nanoscale
Abstract not provided.
Rapid Screening of Cladding Materials for Generation IV Nuclear Reactors
Abstract not provided.
Results 451–475 of 527