Your search keyword '"Nilson PM"' showing total 3 results

1. Probing atomic physics at ultrahigh pressure using laser-driven implosions.

Author

Hu SX, Bishel DT, Chin DA, Nilson PM, Karasiev VV, Golovkin IE, Gu M, Hansen SB, Mihaylov DI, Shaffer NR, Zhang S, and Walton T

Abstract

Spectroscopic measurements of dense plasmas at billions of atmospheres provide tests to our fundamental understanding of how matter behaves at extreme conditions. Developing reliable atomic physics models at these conditions, benchmarked by experimental data, is crucial to an improved understanding of radiation transport in both stars and inertial fusion targets. However, detailed spectroscopic measurements at these conditions are rare, and traditional collisional-radiative equilibrium models, based on isolated-atom calculations and ad hoc continuum lowering models, have proved questionable at and beyond solid density. Here we report time-integrated and time-resolved x-ray spectroscopy measurements at several billion atmospheres using laser-driven implosions of Cu-doped targets. We use the imploding shell and its hot core at stagnation to probe the spectral changes of Cu-doped witness layer. These measurements indicate the necessity and viability of modeling dense plasmas with self-consistent methods like density-functional theory, which impact the accuracy of radiation transport simulations used to describe stellar evolution and the design of inertial fusion targets., (© 2022. The Author(s).)

Published

2022

2. Interspecies radiative transition in warm and superdense plasma mixtures.

Author

Hu SX, Karasiev VV, Recoules V, Nilson PM, Brouwer N, and Torrent M

Abstract

Superdense plasmas widely exist in planetary interiors and astrophysical objects such as brown-dwarf cores and white dwarfs. How atoms behave under such extreme-density conditions is not yet well understood, even in single-species plasmas. Here, we apply thermal density functional theory to investigate the radiation spectra of superdense iron-zinc plasma mixtures at mass densities of ρ = 250 to 2000 g cm -3 and temperatures of kT = 50 to 100 eV, accessible by double-shell-target implosions. Our ab initio calculations reveal two extreme atomic-physics phenomena-firstly, an interspecies radiative transition; and, secondly, the breaking down of the dipole-selection rule for radiative transitions in isolated atoms. Our first-principles calculations predict that for superdense plasma mixtures, both interatomic radiative transitions and dipole-forbidden transitions can become comparable to the normal intra-atomic Kα-emission signal. These physics phenomena were not previously considered in detail for extreme high-density plasma mixtures at super-high energy densities.

Published

2020

3. Time-resolved compression of a capsule with a cone to high density for fast-ignition laser fusion.

Author

Theobald W, Solodov AA, Stoeckl C, Anderson KS, Beg FN, Epstein R, Fiksel G, Giraldez EM, Glebov VY, Habara H, Ivancic S, Jarrott LC, Marshall FJ, McKiernan G, McLean HS, Mileham C, Nilson PM, Patel PK, Pérez F, Sangster TC, Santos JJ, Sawada H, Shvydky A, Stephens RB, and Wei MS

Abstract

The advent of high-intensity lasers enables us to recreate and study the behaviour of matter under the extreme densities and pressures that exist in many astrophysical objects. It may also enable us to develop a power source based on laser-driven nuclear fusion. Achieving such conditions usually requires a target that is highly uniform and spherically symmetric. Here we show that it is possible to generate high densities in a so-called fast-ignition target that consists of a thin shell whose spherical symmetry is interrupted by the inclusion of a metal cone. Using picosecond-time-resolved X-ray radiography, we show that we can achieve areal densities in excess of 300 mg cm(-2) with a nanosecond-duration compression pulse--the highest areal density ever reported for a cone-in-shell target. Such densities are high enough to stop MeV electrons, which is necessary for igniting the fuel with a subsequent picosecond pulse focused into the resulting plasma.

Published

2014