Your search keyword '"Goncharov, Valeri N."' showing total 4 results

1. Time-dependent density-functional theory study on nonlocal electron stopping for inertial confinement fusion.

Author

Nichols, Katarina A., Hu, S. X., White, Alexander J., Shaffer, Nathaniel R., Mihaylov, Deyan I., Arnold, Brennan, Goncharov, Valeri N., Karasiev, Valentin V., and Collins, Lee A.

Subjects

INERTIAL confinement fusion, TIME-dependent density functional theory, ELECTRON transport, STANDARD model (Nuclear physics), ELECTRONS

Abstract

Understanding laser–target coupling is of the utmost importance for achieving high performance in laser-direct-drive (LDD) inertial confinement fusion (ICF) experiments. Thus, accurate modeling of electron transport and deposition through ICF-relevant materials and conditions is necessary to quantify the total thermal conduction and ablation. The stopping range is a key transport quantity used in thermal conduction models; in this work, we review the overall role that the electron mean free path (MFP) plays in thermal conduction and hydrodynamic simulations. The currently used modified Lee–More model employs various physics approximations. We discuss a recent model that uses time-dependent density functional theory (TD-DFT) to eliminate these approximations in both the calculation of the electron stopping power and corresponding MFP in conduction zone polystyrene (CH) plasma. In general, the TD-DFT calculations showed a larger MFP (lower stopping power) than the standard modified Lee–More model. Using the TD-DFT results, an analytical model for the electron deposition range, λ T D − DFT (ρ , T , K) , was devised for CH plasmas between ρ = [ 0.05 − 1.05 ] g / cm 3 , k B T = [ 100 − 1000 ] eV. We implemented this model into LILAC, for simulations of a National Ignition Facility-scale LDD implosion and compared key physics quantities to ones obtained by simulations using the standard model. The implications of the obtained results and the path moving forward to calculate this same quantity in conduction-zone deuterium–tritium plasmas are further discussed, to hopefully close the understanding gap for laser target coupling in LDD-ICF simulations. [ABSTRACT FROM AUTHOR]

Published

2024

2. LPSE: A 3-D wave-based model of cross-beam energy transfer in laser-irradiated plasmas

Author

Myatt, Jason F., Shaw, John G., Follett, Russell K., Edgell, Dana H., Froula, Dustin H., Palastro, John P., and Goncharov, Valeri N.

Published

2019

3. Cryogenic Deuterium and Deuterium-Tritium Direct–Drive Implosions on Omega.

Author

Goncharov, Valeri N.

Published

2013

4. Thermal conductivity of a laser plasma.

Author

Shaffer NR, Maximov AV, and Goncharov VN

Abstract

We present a model of the electron thermal conductivity of a laser-produced plasma. The model, supported by Vlasov-Fokker-Planck simulations, predicts that laser absorption reduces conductivity by forcing electrons out of a Maxwell-Boltzmann equilibrium, which results in the depletion of both low-velocity bulk electrons and high-velocity tail electrons. We show that both the bulk and tail electrons approximately follow super-Gaussian distributions, but with distinct exponents that each depend on the laser intensity and wavelength through the parameter α=Zv_{E}^{2}/v_{T}^{2}. For a value of α=0.5, tail depletion reduces the thermal conductivity to half its zero-intensity value. We present our results as simple analytic fits that can be readily implemented in any radiation-hydrodynamics code or used to correct the local limit of nonlocal conduction models.

Published

2023