Microwave Based Lifetime Measurements and Analysis for Detector Materials
Abstract not provided.
Publications
Radiation Induced Defects in InAs/InAsSb Type II Superlattices Characterized with Time-resolved Microwave Reflectance and DFT
Abstract not provided.
Workfunction of Pt thin films with disorder
Abstract not provided.
Field emission from Pt thin films with disorder
Abstract not provided.
Computing properties of Pt surfaces for understanding electron emission
Abstract not provided.
Advancing electrode models for PIC-DSMC simulation of vacuum discharge between real surfaces
Abstract not provided.
CHARACTERIZING THE INFLUENCE OF ELECTRODE SURFACE STRUCTURE ON FIELD EMISSION
Abstract not provided.
Field emission from Pt thin films with disorder
Abstract not provided.
Modeling field emission from real surfaces
Abstract not provided.
In-situ Annealing Studies of Radiation Induced Defects in InAs/InAsSb Type-II Superlattices under Ion Irradiation
Abstract not provided.
CHARACTERIZING THE INFLUENCE OF ELECTRODE SURFACE STRUCTURE ON FIELD EMISSION
Abstract not provided.
Work function of platinum thin films with disorder
Abstract not provided.
Understanding phosphorus donor insertion on Si(001) from PH3 dissociation in dimer windows formed by hydrogen lithography
Abstract not provided.
From narrow gap to ultra-wide band gap systems: End of band gap problem excuses for defect calculations
Abstract not provided.
Effects of 4.5 MeV and 63 MeV Proton Irradiation on Carrier Lifetime of InAs/InAsSb Type-II Superlattices
Abstract not provided.
Comparing Radiation Induced Lifetime Degradation in InAs/InAsSb Type-II Superlattices using 4.5 and 63 MeV Proton Irradiations
Abstract not provided.
Atomic-precision fabrication and metrology for epitaxial Si quantum devices
Abstract not provided.
Vacuum Field Emission Models Measurements and Simulations
Abstract not provided.
The journey from forensic to predictive materials science using density functional theory
Modelling and Simulation in Materials Science and Engineering
Abstract not provided.
Modeling charged defects and defect levels in semiconductors and oxides with DFT: An improved inside-out perspective
Abstract not provided.
Atomically Precise Single Donor Placement by STM Lithography
Abstract not provided.
The Defect Band Gap
Abstract not provided.
Discriminating a deep gallium antisite defect from shallow acceptors in GaAs using supercell calculations
Physical Review B
For the purposes of making reliable first-principles predictions of defect energies in semiconductors, it is crucial to distinguish between effective-mass-like defects, which cannot be treated accurately with existing supercell methods, and deep defects, for which density functional theory calculations can yield reliable predictions of defect energy levels. The gallium antisite defect GaAs is often associated with the 78/203 meV shallow double acceptor in Ga-rich gallium arsenide. Within a conceptual framework of level patterns, analyses of structure and spin stabilization can be used within a supercell approach to distinguish localized deep defect states from shallow acceptors such as BAs. This systematic approach determines that the gallium antisite supercell results has signatures inconsistent with an effective mass state and cannot be the 78/203 shallow double acceptor. The properties of the Ga antisite in GaAs are described, total energy calculations that explicitly map onto asymptotic discrete localized bulk states predict that the Ga antisite is a deep double acceptor and has at least one deep donor state.
Discriminating a deep defect from shallow acceptors in supercell calculations: Gallium antisite in GaAs
Abstract not provided.
Developing mechanical properties of metal triodes for models of agig
Abstract not provided.
Results 26–50 of 124
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