Nanoindentation and TEM Characterization of 316L Stainless Steels
Abstract not provided.
Publications
Altering Thermal Boundary Conductance in Al/Al2O3 and Al/Si Boundaries Using Ion Beam Radiation
Abstract not provided.
Evidence and Crystallography of Metastable hcp Phase Grains in As- Deposited Nanocrystalline Nickel Films
Proposed for publication in Scripta Materialia.
Abstract not provided.
In situ Ion Irradiation TEM at Sandia's IBL
Abstract not provided.
In situ and Ex situ TEM Ion Irradiation for Cladding Materials
Abstract not provided.
Investigation of Intergranular Phenomena in Sigma3 CSL Grain Boundaries Exposed to Extreme Environments
Abstract not provided.
Characterization of Nanoscale hcp Phase Nickel in a fcc Phase Nickel Thin Film
Abstract not provided.
Understanding the Structure of Nanograined Polycrystalline Materials by in-situand Precession Electron Microscopy
Abstract not provided.
Modeling and Micrograph Simulation of Ions Damage on Crystals
Abstract not provided.
Understanding Texture Evolution in Nanocrystalline Nickel Films
Abstract not provided.
Understanding Microstructural Changes in Cladding Materials:Plans for In-situ TEM Ion Irradiation Experiments at Sandia
Abstract not provided.
Fast neutron environments
The goal of this LDRD project is to develop a rapid first-order experimental procedure for the testing of advanced cladding materials that may be considered for generation IV nuclear reactors. In order to investigate this, a technique was developed to expose the coupons of potential materials to high displacement damage at elevated temperatures to simulate the neutron environment expected in Generation IV reactors. This was completed through a high temperature high-energy heavy-ion implantation. The mechanical properties of the ion irradiated region were tested by either micropillar compression or nanoindentation to determine the local properties, as a function of the implantation dose and exposure temperature. In order to directly compare the microstructural evolution and property degradation from the accelerated testing and classical neutron testing, 316L, 409, and 420 stainless steels were tested. In addition, two sets of diffusion couples from 316L and HT9 stainless steels with various refractory metals. This study has shown that if the ion irradiation size scale is taken into consideration when developing and analyzing the mechanical property data, significant insight into the structural properties of the potential cladding materials can be gained in about a week.
Recent developments in the use of a microfluidic stage for in situ TEM studies
Abstract not provided.
Influence of anisotropy on thermal boundary conductance at solid interfaces
Physical Review B
Abstract not provided.
The Feasibility and Development of an In situ Ion Irradiation TEM at Sandia National Laboratories
Abstract not provided.
Transmission Electron Microscopy & Tomography Investigation into the Morphological Evolution of Ge upon Ion Irradiation
Abstract not provided.
Investigating Corrosion at the Nanoscale
Abstract not provided.
Understanding the Structure of Nanograined Polycrystalline Materials by in-situand Precession Electron Microscopy
Abstract not provided.
In-situ Ion Beam Induced Luminescence/Imaging of Scintillating Materials
Abstract not provided.
Potential for In situ Transmission Electron Microscopy (TEM) Electron and Ion Irradiation of Living Cells
Abstract not provided.
The potential for In situ Transmission Electron Microscopy (TEM) of electron and ion irradiation of living cells
Abstract not provided.
In-situ Ion Beam Induced Luminescence/Imaging of Scintillating Materials
Abstract not provided.
Nanoimplantation and In situ TEM Ion Irradiation at Sandia National Laboratories
Abstract not provided.
Reduction in thermal boundary conductance due to proton implantation in silicon and sapphire
Applied Physics Letters
Abstract not provided.
New Ion Beam Lab:Capabilities Applicable to MOFs
Abstract not provided.
Results 476–500 of 527