Electronic temperatures, densities, and plasma x-ray emission of a 14.5 GHz electron-cyclotron resonance ion source

Gumberidze, A.; Trassinelli, Martino; Adrouche, Nacer; Szabo, Csilla I.; Indelicato, P.; Haranger, F.; Isac, Jean-Michel; Lamour, Emily; Bigot, Éric-Olivier Le; Merot, Jacques; Prigent, Christophe; Rozet, J.P.; Vernhet, Dominique

doi:10.1063/1.3316805

Cited by 58 publications

(51 citation statements)

References 31 publications

(56 reference statements)

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“…Analyses of the Bremsstrahlung spectrum generated by electrons when colliding with the other plasma particles provide a tool for diagnosing high temperature electrons [14,15]. In general, if the X-ray spectrum is known, it is possible to find the electron density and the temperature of the plasma that generated it [14].…”

Section: Discussionmentioning

confidence: 99%

Experimental Characterization of an Overdense Plasma in a Compact Ion Source

Castro

Romano²,

Altana

et al. 2015

Acta Polytech

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Abstract. Electron Cyclotron Resonance Ion Sources (ECRIS) are compact plasma-based machines able to feed particle accelerators with high intensity beams of multi-charged ions. ECRIS plasmas are density-limited, since they are sustained by E.M. wave propagation up to a cut-off density value. In the past, the only way to improve ECRIS performance was to increase the microwave frequency and the magnetic field strength to satisfy the ECR condition. A different plasma heating mechanism is being applied at INFN-LNS. It is based on Electron Bernstein Waves (EBW), i.e., electrostatic waves which do not suffer any density cut-off. Highlights concerning preliminary signatures of EBW formation and subsequent absorption are given here.

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Section: Discussionmentioning

confidence: 99%

Experimental Characterization of an Overdense Plasma in a Compact Ion Source

Castro

Romano²,

Altana

et al. 2015

Acta Polytech

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“…The electron distribution function f (E) is strongly non-Maxwellian and can be represented by two populations [13]: a cold one (energies up to 10 keV) and a hot one (energies of several tens of keV); the latter is well confined inside a closed egg-shaped surface centered around the source main axis. Barué et al [13] and Gumberidze et al [5] studied experimentally the energy distribution of the hot electrons observing bremsstrahlung and electron cyclotron emission.…”

Section: Distribution Of Electron Energies In the Plasmamentioning

confidence: 99%

“…Their plasmas are also more and more used as powerful sources of radiation, whether to provide vacuum-ultraviolet radiation sources [1] or intense sources of highly charged ion x rays [2,3]. The radiation emitted by the ions in the plasma can be used for plasma diagnostic [4,5], for spectrometer characterization [6], and to provide accurate transition energies of highly charged ions.…”

Section: Introductionmentioning

confidence: 99%

X-ray-spectroscopy analysis of electron-cyclotron-resonance ion-source plasmas

et al. 2010

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Analysis of x-ray spectra emitted by highly charged ions in an electron-cyclotron-resonance ion source (ECRIS) may be used as a tool to estimate the charge-state distribution (CSD) in the source plasma. For that purpose, knowledge of the electron energy distribution in the plasma, as well as the most important processes leading to the creation and de-excitation of ionic excited states are needed. In this work we present a method to estimate the ion CSD in an ECRIS through the analysis of the x-ray spectra emitted by the plasma. The method is applied to the analysis of a sulfur ECRIS plasma.

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“…The DCS was designed and built to operate in vacuum and to be attached to an Electron Cyclotron Resonance Ion Source (ECRIS) to directly observe the highly charged ion plasma [42]. The DCS described in [9], in addition to providing reference-free line energy measurements with a relative , can also be a tool to determine transition probabilities and ion temperatures inside a highly charged ion plasma [43].…”

Section: Crystals For the Lkb Vacuum Double Crystal Spectrometermentioning

confidence: 99%

The Lattice Spacing Variability of Intrinsic Float-Zone Silicon

Kessler¹,

Szabo²,

Cline³

et al. 2017

J. RES. NATL. INST. STAN.

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Precision lattice spacing comparison measurements at the National Institute of Standards and Technology (NIST) provide traceability of X-ray wavelength and powder diffraction standards to the international system of units (SI). Here, we both summarize and document key measurements from the last two decades on six lots of intrinsic float-zone silicon, including unpublished results and recent internal-consistency checks. The comparison measurements link the unknown lattice spacing of a test crystal to a standard crystal for which the lattice spacing has been accurately determined by X-ray/optical interferometry in units traceable to the definition of the meter. The crystal that serves as the standard in all the comparisons is WASO 04, for which the lattice spacing is known with a relative uncertainty of 5 × 10 ; taking material variability into account, measurements yield relative uncertainties for the test materials of a few tens of nanometers. It is observed that in the case of nearly perfect modern intrinsic float-zone silicon, the variability of the lattice spacing is sufficiently small that for most diffraction applications, a recommended reference value may be used.

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Electronic temperatures, densities, and plasma x-ray emission of a 14.5 GHz electron-cyclotron resonance ion source

Cited by 58 publications

References 31 publications

Experimental Characterization of an Overdense Plasma in a Compact Ion Source

Experimental Characterization of an Overdense Plasma in a Compact Ion Source

X-ray-spectroscopy analysis of electron-cyclotron-resonance ion-source plasmas

The Lattice Spacing Variability of Intrinsic Float-Zone Silicon

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