2019
DOI: 10.1103/physrevresearch.1.033216
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Impact of free electron degeneracy on collisional rates in plasmas

Abstract: Degenerate plasmas, in which quantum effects dictate the behavior of free electrons, are ubiquitous on earth and throughout space. Transitions between bound and free electron states determine basic plasma properties, yet the effects of degeneracy on these transitions have only been theorized. Here, we use an x-ray free electron laser to create and characterize a degenerate plasma. We observe a core electron fluorescence spectrum that cannot be reproduced by models that ignore free electron degeneracy. We show … Show more

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Cited by 3 publications
(3 citation statements)
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“…At higher temperatures, even the models with similar treatments of continuum lowering diverge significantly. Finally, we note that while a partially degenerate electron energy distribution can significantly reduce collisional rates [1,38,39] when temperatures are near the Fermi energy (12 -16 eV for the two cases), the impact is not evident here because degenerate rates still follow the detailed balance relations that enforce LTE populations, and in steady-state without an external radiation field the lower-temperature cases here are firmly in LTE. Detailed charge state distributions and emission spectra are given in Fig.…”
Section: Steady-state Almentioning
confidence: 86%
“…At higher temperatures, even the models with similar treatments of continuum lowering diverge significantly. Finally, we note that while a partially degenerate electron energy distribution can significantly reduce collisional rates [1,38,39] when temperatures are near the Fermi energy (12 -16 eV for the two cases), the impact is not evident here because degenerate rates still follow the detailed balance relations that enforce LTE populations, and in steady-state without an external radiation field the lower-temperature cases here are firmly in LTE. Detailed charge state distributions and emission spectra are given in Fig.…”
Section: Steady-state Almentioning
confidence: 86%
“…Such high-density degenerate plasmas may be directly created via ultraviolet or x-ray free electron lasers (Williams et al. 2019). Also, by varying the laser intensity, partially or fully degenerate plasmas can also be produced in the laboratory (Hayes et al.…”
Section: Introductionmentioning
confidence: 99%
“…in the interior of white dwarfs, neutron star and magnetars with particle number density ranging from 10 26 cm −3 to 10 34 cm −3 . Such high-density degenerate plasmas may be directly created via ultraviolet or x-ray free electron lasers (Williams et al 2019). Also, by varying the laser intensity, partially or fully degenerate plasmas can also be produced in the laboratory (Hayes et al 2020), which makes laser produced plasmas useful in recreating astrophysical plasmas in the laboratory.…”
Section: Introductionmentioning
confidence: 99%