797870 In the fast ignition concept for inertial fusion energy, high-intensity short-pulse lasers are used to create energetic particles (protons and relativistic electrons) that propagate to the fuel within a compressed capsule. The efficient transport of these energetic particles to the fuel is a… More

In the fast ignition concept for inertial fusion energy, high-intensity short-pulse lasers are used to create energetic particles (protons and relativistic electrons) that propagate to the fuel within a compressed capsule. The efficient transport of these energetic particles to the fuel is a key… More

This Small Business Innovation Research (SBIR) Phase I project will pursue the development of novel plasma technologies for creating highly efficient, short-wavelength radiation sources for use in next generation semiconductor chip manufacturing. The development of plasma radiation sources that… More

The objective of this proposal is to develop and validate first-principles modeling tools that will significantly advance the use of spectroscopic techniques for identifying materials present in hypervelocity impact events. Impact flash spectroscopy (IFS) has the potential to identify the presence… More

The objective of this project is to develop and benchmark advanced physics-based modeling techniques that can be used to reliably predict radiative signatures emitted during the early-time impact flash phase of hypervelocity impact events. Impact flash spectroscopy (IFS) has the potential to… More

The objective of this proposal is to develop advanced radiation transport modeling techniques that accurately and efficiently treat transport in media having widely varying optical properties; in particular, hot gases and plasmas with optical depths ranging from the optically thin to the optically… More

The objective of this proposal is to develop advanced radiation transport modeling techniques that accurately and efficiently treat transport in media having widely varying optical properties; in particular, hot gases and plasmas with optical depths ranging from the optically thin to the optically… More

The interplay between accurate modeling and well-diagnosed experiments plays a critical role in advancing our understanding of high energy density laboratory plasmas (HEDLPs). It is vital to have high-fidelity computational physics tools that have well-tested radiation physics modeling, and that are… More