Research

Bioscience:

• Modeling of Blood Flow

Extreme Ultraviolet Lithography (EUV):

• Modeling and Simulation of Discharge Produced Plasma

• Development of Plasma-Facing Materials

• Fundamental Atomistic Simulations by Molecular Dynamics and Monte Carlo Methods

• Multiscale Hybrid Molecular Dynamics Model (HyDyn)

• Monte Carlo Simulation of Nanostructure Formation on Surface

• Atomistic Simulation of Shallow Junction Formation in Silicon

• Models of Highly-Charged Ion Interactions with Solid Surfaces

• Atomistic Models of RF Vacuum Breakdown

Global Nuclear Energy Protocol (GNEP):

• Advanced Fission Reactor Design

High Energy Physics (HEP):

• Modeling High-Power Interactions with Target Materials

• Monte Carlo Simulation of Nanostructure Formation on Surface

• Atomistic Simulation of Shallow Junction Formation in Silicon

• Models of Highly-Charged Ion Interactions with Solid Surfaces

• Atomistic Models of RF Vacuum Breakdown

Homeland Defense:

• Modeling High-Power Interactions with Target Materials

IMPACT:

• Interaction of Materials with Charged Particles and Components Testing (IMPACT)

Inertial Fusion Energy (IFE):

• Modeling High-Power Interactions with Target Materials

• Development of Plasma-Facing Materials

• Fundamental Atomistic Simulations by Molecular Dynamics and Monte Carlo Methods

Magnetic Fusion Energy (MFE):

• Modeling High-Power Interactions with Target Materials

• Development of Plasma-Facing Materials

• Fundamental Atomistic Simulations by Molecular Dynamics and Monte Carlo Methods

• Multiscale Hybrid Molecular Dynamics Model (HyDyn)

Nuclear Energy Physics (NEP):

• Modeling High-Power Interactions with Target Materials

• Modeling for the Rare Isotope Accelerator

Space Propulsion:

• Modeling High-Power Interactions with Target Materials

PRIME:

• Facility for Particle/Radiation Interaction with Matter Experiments (PRIME)