Your search keyword '"Stefan Briefi"' showing total 34 results

1. Impact of Internal Faraday Shields on RF Driven Hydrogen Discharges

Author

David Rauner, Dominikus Zielke, Stefan Briefi, and Ursel Fantz

Subjects

radio frequency discharge, hydrogen, Faraday shield, inductively coupled plasma, helicon, power transfer efficiency, Physics, QC1-999, Plasma physics. Ionized gases, QC717.6-718.8

Abstract

At RF plasma reactors operated at high power, internal Faraday shields are required to shield dielectric vessel or windows from erosion due to isotropic heat and particle fluxes. By utilizing a flexible and diagnostically well-equipped laboratory setup, crucial effects that accompany the application of internal Faraday shields at low-pressure hydrogen (and deuterium) RF discharges are identified and quantified in this contribution. Both an inductively coupled plasma (ICP) utilizing a helical coil and a low-field helicon discharge applying a Nagoya-type III antenna at magnetic fields of up to 12 mT are investigated. Discharges are driven at 4 MHz and in the pressure range between 0.3 and 10 Pa while the impact of the Faraday shields on both the RF power transfer efficiency and spectroscopically determined bulk plasma parameters (electron density and temperature, atomic density) is investigated. Three main effects are identified and discussed: (i) due to the Faraday shield, the measured RF power transfer efficiency is globally reduced. This is mainly caused by increased power losses due to induced eddy currents within the electrostatic shield, as accompanying numerical simulations by a self-consistent fluid model demonstrate. (ii) The Faraday shield reduces the atomic hydrogen density in the plasma by one order of magnitude, as the recombination rate of atoms on the metallic (copper) surfaces of the shield is considerably higher compared to the dielectric quartz walls. (iii) The Faraday shield suppresses the transition of the low-field helicon setup to a wave heated regime at the present conditions. This is attributed to a change of boundary conditions for wave propagation, as the plasma is in direct contact with the conductive surfaces of the Faraday shield rather than being operated in a laterally fully dielectric vessel.

Published

2022

2. A Novel Approach to β-Decay: PANDORA, a New Experimental Setup for Future In-Plasma Measurements

Author

David Mascali, Domenico Santonocito, Simone Amaducci, Lucio Andò, Vincenzo Antonuccio, Sándor Biri, Alfio Bonanno, Vincenza Piera Bonanno, Stefan Briefi, Maurizio Busso, Luigi Celona, Luigi Cosentino, Sergio Cristallo, Marco Cuffiani, Costantino De Angelis, Giacomo De Angelis, Davide De Salvador, Loreto Di Donato, Jean-Eric Ducret, Aref Eshkevar Vakili, Ursel Fantz, Alessio Galatà, Carmelo Sebastiano Gallo, Santo Gammino, Tommaso Isernia, Hannu Koivisto, Karl-Ludwig Kratz, Risto Kronholm, Marco La Cognata, Silvia Leoni, Andrea Locatelli, Mario Maggiore, Fabio Maimone, Luciana Malferrari, Giorgio Mancini, Laurent Maunoury, Giorgio Sebastiano Mauro, Maria Mazzaglia, Alberto Mengoni, Andrea Miraglia, Bharat Mishra, Mario Musumeci, Daniel Ricardo Napoli, Eugenia Naselli, Fabrizio Odorici, Libero Palladino, Giuseppe Palmisano, Santi Pavone, Salvatore Pennisi, Albino Perego, Angelo Pidatella, Richard Rácz, Riccardo Reitano, Danilo Rifuggiato, Matteo Rinaldi, Antonio Domenico Russo, Filippo Russo, Gaetano Schillaci, Stefano Selleri, Stefano Simonucci, Gino Sorbello, Roberta Spartà, Simone Taioli, Klaus Tinschert, Giuseppe Torrisi, Antonio Trifirò, Sedina Tsikata, Aurora Tumino, Diego Vescovi, and Luca Vincetti

Subjects

beta decay, nucleosynthesis, plasma trap, plasma diagnostics, Elementary particle physics, QC793-793.5

Abstract

Theoretical predictions as well as experiments performed at storage rings have shown that the lifetimes of β-radionuclides can change significantly as a function of the ionization state. In this paper we describe an innovative approach, based on the use of a compact plasma trap to emulate selected stellar-like conditions. It has been proposed within the PANDORA project (Plasmas for Astrophysics, Nuclear Decay Observation and Radiation for Archaeometry) with the aim to measure, for the first time in plasma, nuclear β-decay rates of radionuclides involved in nuclear-astrophysics processes. To achieve this task, a compact magnetic plasma trap has been designed to reach the needed plasma densities, temperatures, and charge-states distributions. A multi-diagnostic setup will monitor, on-line, the plasma parameters, which will be correlated with the decay rate of the radionuclides. The latter will be measured through the detection of the γ-rays emitted by the excited daughter nuclei following the β-decay. An array of 14 HPGe detectors placed around the trap will be used to detect the emitted γ-rays. For the first experimental campaign three isotopes, 176Lu, 134Cs, and 94Nb, were selected as possible physics cases. The newly designed plasma trap will also represent a tool of choice to measure the plasma opacities in a broad spectrum of plasma conditions, experimentally poorly known but that have a great impact on the energy transport and spectroscopic observations of many astrophysical objects. Status and perspectives of the project will be highlighted in the paper.

Published

2022

3. Review Article

Author

Ursel Fantz, A. Heiler, D. Wünderlich, Stefan Briefi, and C. Wimmer

Subjects

Materials science, Hydrogen, Power station, Materials Science (miscellaneous), Nuclear engineering, QC1-999, Biophysics, General Physics and Astronomy, chemistry.chemical_element, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, Ion, neutral beam injection, ITER, 0103 physical sciences, Physical and Theoretical Chemistry, 010306 general physics, ion source, Mathematical Physics, Physics, RF power amplifier, ICP, Plasma, negative hydrogen ion, Neutral beam injection, Ion source, chemistry, Beam (structure)

Abstract

The neutral beam injection systems for the international fusion experiment ITER used for heating, current drive, and diagnostic purposes are based on RF-driven negative hydrogen ion sources with a source area of roughly 0.9 m × 1.9 m. The sources operate at 0.3 Pa in hydrogen and in deuterium using a total available RF generator power of 800 kW per source at a frequency of 1 MHz. In order to fulfill the challenging requirements for ITER and beyond (like a DEMOnstration power plant, DEMO), worldwide developments are underway addressing the topics of plasma generation, ion extraction together with the issue of reducing and stabilizing the co-extracted electron current, and the beam properties. At the example of the activities at the ITER prototype source and the size scaling experiment ELISE, the present status and its challenges are summarized. The RF power transfer efficiency of these sources is only about 65% in maximum, giving significant room for improvements to relax the demands on the RF generator and ensure reliable operation. The plasma uniformity in front of the large extraction system is the result of plasma drifts. They have a huge impact on the nonuniformity of the co-extracted electrons and influence the ions and thus the beam properties as well. Understanding the optics of such large beams composed of hundreds of beamlets is a crucial task and is under continuous improvement. The main challenge, however, is still the fulfillment of the ITER requirements for deuterium, in particular, for long pulses. The management of caesium, which is evaporated into the source to generate sufficient negative ions by the surface conversion process, is one of the keys for stable and reliable operation.

Published

2021

4. Self-consistent fluid model for simulating power coupling in hydrogen ICPs at 1 MHz including the nonlinear RF Lorentz force

Author

Stefan Briefi, S. Lishev, D. Zielke, Ursel Fantz, and D. Rauner

Subjects

010302 applied physics, Physics, Hydrogen, chemistry.chemical_element, Self consistent, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, symbols.namesake, Nonlinear system, chemistry, Quantum electrodynamics, 0103 physical sciences, symbols, ddc:530, Power coupling, Lorentz force

Abstract

Radio frequency (RF) power coupling in inductively coupled plasmas is investigated numerically using a self-consistent fluid model. Hydrogen discharges are simulated at pressures from 0.3–10 Pa and at RF powers of around 1 kW. At the low excitation frequency of 1 MHz a high magnetic RF field of around 30 G is generated by the RF coil, meaning that discharges at low pressures are in the nonlinear skin effect regime. Therefore, a description of the RF power coupling by simple collisional Joule heating is not appropriate. Moreover, models that account for collisionless heating by means of a stochastic collision frequency or as diffusion of the RF current density (as is state of the art for discharges operated in the anomalous skin effect regime at higher frequencies of e.g. 13.56 MHz) are incapable of describing the RF power coupling in the nonlinear skin effect regime properly. This is due to their total neglect or simplified treatment of the RF Lorentz force. Instead, this work demonstrates that the RF power coupling mechanism for discharges operating at low RF in the nonlinear skin effect regime can be described by an electron momentum balance retaining the nonlinear RF Lorentz force as well as electron inertia and advection. The crucial role of the RF Lorentz force in generating the RF plasma current density and thus in shaping the plasma parameter profiles is validated successfully with experimentally obtained electrical and spatially resolved plasma parameters for pressures as low as 0.5 Pa. Below this pressure the results obtained from the model and the ones from the experiment diverge. Most likely this is caused by a sudden change in the electron distribution function at the lowest pressures.

Published

2021

5. Absolute radiometric calibration of a VUV spectrometer in the wavelength range 46-300 nm

Author

C. Fröhler-Bachus, Ursel Fantz, Roland Friedl, and Stefan Briefi

Subjects

Radiation, Materials science, 010504 meteorology & atmospheric sciences, Spectrometer, business.industry, Lyman series, Synchrotron radiation, Balmer series, 01 natural sciences, Atomic and Molecular Physics, and Optics, symbols.namesake, Optics, Optical Emission Spectrometer, Calibration, Emissivity, symbols, ddc:530, business, Radiometric calibration, Spectroscopy, 0105 earth and related environmental sciences

Abstract

Vacuum ultraviolet (VUV) radiation corresponds to photon energies exceeding 6.2 eV and provides access to atomic and molecular resonant transitions in various plasmas. Determining population densities of electronic levels directly connected to the ground state requires an absolute intensity calibration of the VUV spectrometer. For this purpose, synchrotron radiation from electron storage rings is the typical primary standard source associated with transport effort and operating costs. Alternatively, a complex procedure using several secondary standards and discharges directly at the setup in use can be applied. In this work, an absolute intensity calibration avoiding synchrotron radiation to cover the wavelength range 46–300 nm accessible with two detectors—a photomultiplier tube and a channel electron multiplier—is presented. A combination of different standard sources—two deuterium arc lamps, branching-ratios of a nitrogen plasma and a high current hollow cathode—is applied for the relative calibration. The absolute calibration is based on simultaneous measurements of atomic lines in a low pressure helium discharge with the VUV spectrometer and an absolutely calibrated optical emission spectrometer. Special focus is laid on the uncertainties of the relative and absolute calibration depending on the wavelength range. The applicability of the intensity calibration is demonstrated at a hydrogen plasma in the wavelength range 80–300 nm. Using the emissivity of the Lyman series, population densities of the first six excited atomic states are calculated considering opacity effects. The excellent agreement with results from the Balmer series by optical emission spectroscopy manifests the high validity of the performed absolute intensity calibration.

Published

2020

6. A revised comprehensive approach for determining the H2 and D2 rovibrational population from the Fulcher-α emission in low temperature plasmas

Author

Stefan Briefi and Ursel Fantz

Subjects

education.field_of_study, Materials science, Population, ddc:530, Rotational–vibrational spectroscopy, Plasma, Atomic physics, Condensed Matter Physics, education

Abstract

The emission of the Fulcher- α d 3 Π u → a 3 Σ g + transition is well-known for providing access to the rovibrational population of the hydrogen molecule in low temperature plasmas by means of optical emission spectroscopy. A revised comprehensive approach is developed for the evaluation that omits several simplifying assumptions, which are often made. The rovibrational distribution is directly calculated in the X 1 Σ g + state considering the typically observed hockey-stick population. The projection into the d 3Π u state is performed via vibrationally resolved electron impact excitation cross sections and radiative decay into the a 3 Σ g + is considered via vibrationally resolved transition probabilities. The obtained steady-state population is fitted to the experimentally measured one via varying the population parameters in the electronic ground state. The impact of this evaluation routine compared to the simplified ones is demonstrated both for H2 and D2 at two experiments: a standard CW low-power laboratory ICP and the pulsed high-power negative ion source plasma of the Linac4 accelerator at CERN. This assessment demonstrates that especially the simplification of measuring only the first five rotational emission lines (i.e. neglecting the rotational hockey-stick distribution) can affect the evaluation results significantly. In the application example, this leads to an overestimation of the gas temperature up to a factor of nine and to an underestimation of the determined intensity of the full Fulcher-α transition (required for applying collisional radiative models) up to a factor of three.

Published

2020

7. Multidiagnostics investigation of the role of the magnetic field profile in a simple mirror trap

Author

Stefan Briefi, M. Mazzaglia, David Mascali, R. Miracoli, Giuseppe Castro, and Ursel Fantz

Subjects

Physics, Nuclear and High Energy Physics, Electron density, Physics and Astronomy (miscellaneous), Field (physics), 010308 nuclear & particles physics, Plasma parameters, Surfaces and Interfaces, Plasma, 01 natural sciences, Electron cyclotron resonance, Magnetic field, symbols.namesake, Physics::Plasma Physics, Magnetic trap, 0103 physical sciences, symbols, Langmuir probe, lcsh:QC770-798, lcsh:Nuclear and particle physics. Atomic energy. Radioactivity, Atomic physics, 010306 general physics

Abstract

The impact of the magnetic field profile on the operations of plasma-based Electron Cyclotron Resonance Ion Sources (ECRIS) has been debated and investigated for a long time, and a summary is given by the collection of the so-called ``magnetic scaling laws'', i.e., some rules-of-thumb providing the optimal configuration of the axial and radial confining magnetic fields. Anyway, the optimal configurations have been found just looking at the output beam currents and charge states. Only recently, more advanced experiments have shown that the optimal performances are related to some ``islands" in the parameters space leading to a dense, energetic but stable plasma. A general, systematic characterization of plasma density and temperature as a function of the magnetic scaling, and for different energy domains (i.e., for cold, warm, and hot electrons) is not yet available. This paper presents a multidiagnostics characterization of a hydrogen plasma heated by microwaves at around 6.8 GHz via Electron Cyclotron Resonance, and confined in an axisymmetric simple mirror magnetic trap. Investigation of plasma response to solely the axial field profile gives the unique opportunity to decouple the effect of simple mirror field from the radial components that are, usually, provided by a hexapole. Optical emission spectroscopy, Langmuir probe, and an x-ray silicon drift detector were simultaneously used to evaluate the plasma density and temperature in different energy domains, thus exploring the electron energy distribution function from a few eV to hundreds of keV. Plasma parameters have been measured as a function of the magnetic field profile (in particular by varying the ratio ${B}_{\mathrm{min}}/{B}_{\mathrm{ECR}}$), of the microwave power and of the neutral pressure. Furthermore, for the same scaling, the relative abundances of $H$ atoms and ${H}_{2}$ have been estimated. Data show smooth trends of electron density and temperatures versus microwave power and neutral pressure, but strong and even nonlinear responses as a function of the magnetic field profile variation, allowing us to connect semiempirical scaling laws to changes in plasma parameters.

Published

2019

8. Influence of the excitation frequency on the RF power transfer efficiency of low pressure hydrogen ICPs

Author

Stefan Briefi, D. Rauner, and Ursel Fantz

Subjects

010302 applied physics, Materials science, Equivalent series resistance, business.industry, Plasma parameters, RF power amplifier, Plasma, Condensed Matter Physics, 7. Clean energy, 01 natural sciences, 010305 fluids & plasmas, 0103 physical sciences, Optoelectronics, Maximum power transfer theorem, Skin effect, ddc:530, Inductively coupled plasma, business, Excitation

Abstract

The influence of the excitation frequency on the RF power transfer of inductively heated hydrogen plasmas is investigated in the pressure range between 0.3 and 10 Pa. The experiments are conducted at a cylindrical ICP at frequencies in the range between 1 and 4 MHz and RF powers up to 1 kW. By applying a subtractive method which quantifies the transmission losses within the plasma coil and the RF network, the RF power transfer efficiency is determined. The key plasma parameters of the discharges are measured via optical emission spectroscopy and a double probe. By increasing the frequency from 1 to 4 MHz at a moderate RF power of 520 W, a significant enhancement of the RF power transfer efficiency is observed. It is most prominent at the presently considered low and high pressure limits and allows to reach high efficiencies of up to 95% at pressures between 3 and 5 Pa. While the AC loss resistance of the coil and the RF circuit only displays a relatively weak variation with the applied frequency due to the skin effect, the observed increase of the power transfer efficiency at higher frequencies is dominated by a considerable enhancement of the plasma equivalent resistance. This increased capability of the plasma to absorb the provided power is discussed against the background of collisional and collisionless heating of electrons. Thereby it is demonstrated that the observed behaviour can most likely be attributed to a decreasing difference between the angular excitation frequency and the effective electron collision frequencies. If the RF power is increased however, the RF power transfer efficiency increases globally while frequency induced differences tend to get less pronounced, as the plasma is generally capable of absorbing most of the provided power due to an increasing electron density.

Published

2019

9. The role of photon self-absorption on the H (n = 2) density determination by means of VUV emission spectroscopy and TDLAS in low pressure plasmas

Author

C. Fröhler-Bachus, Ursel Fantz, F. Merk, Stefan Briefi, and Roland Friedl

Subjects

010302 applied physics, Photon, Materials science, 0103 physical sciences, ddc:530, Emission spectrum, Self-absorption, Plasma, Atomic physics, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas

Abstract

The H (n = 2) atomic density determination by means of vacuum ultra-violet (VUV) emission spectroscopy of the Lyman-α line in laboratory low pressure plasmas is strongly affected by self-absorption of emitted photons inside the plasma leading to an underestimation of this density. A correction of the densities obtained from VUV emission spectroscopy measurements is performed by using the escape factor method. The corrections applied can reach orders of magnitude even in low pressure plasmas. Assumptions on the spatial distribution of emitting and absorbing particles as well as on the corresponding line profiles have to be made. Consequently, additional measurements are performed, which raises the requirement of a benchmark of the applied correction procedure. In contrast, tunable diode laser absorption spectroscopy (TDLAS) on the Balmer-α line is a direct measurement of the H (n = 2) density and is thus suitable for a benchmark. For the ICP under consideration, H (n = 2) densities obtained via TDLAS are near 3 × 1015 m−3 whereas uncorrected VUV emission spectroscopy gives values in the range of roughly 1013 m−3 depending on pressure and applied RF power. The calculated escape factors are on the order of 2–8 × 10−3. An excellent agreement with TDLAS is observed by applying them to the results of the VUV emission spectroscopy.

Published

2021

10. RF power transfer efficiency and plasma parameters of low pressure high power ICPs

Author

Stefan Briefi, D. Zielke, and Ursel Fantz

Subjects

010302 applied physics, Materials science, Acoustics and Ultrasonics, Plasma parameters, business.industry, RF power amplifier, Condensed Matter Physics, 01 natural sciences, 7. Clean energy, 010305 fluids & plasmas, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Power (physics), Transfer efficiency, 0103 physical sciences, Optoelectronics, ddc:530, Inductively coupled plasma, business

Abstract

Inductively coupled radio frequency (RF) ion sources operating at 1 MHz under the condition of a low gas pressure of 0.3 Pa are the basis of negative hydrogen/deuterium ionbased neutral beam injection systems of future fusion devices. The applied high RF powers of up to 75 kW impose considerable strain on the RF system and so the RF power transfer efficiency η becomes a crucial measure of the ion source’s reliability. η depends on external parameters such as geometry, RF frequency, power, gas pressure and hydrogen isotope. Hence, η along with the plasma parameters are investigated experimentally at the ITER prototype RF ion source. At only 45%–65% in hydrogen and an increase of around 5% in deuterium, η is found to be surprisingly low in this ion source. The power that is not coupled to the plasma is lost by Joule heating of the RF coil (∼26%) and due to eddy currents in the internal Faraday screen (∼74%). The matching transformer adds up to 8 kW of losses to the system. The low values of η and the high share of the losses in the Faraday screen and the transformer strongly suggest optimization opportunities. At high power densities well above 5 W cm−3, indications for neutral depletion as well as for the ponderomotive effect are found in the pressure and power trends of η and the plasma parameters. The comprehensive data set may serve for comparison with other RF ion sources and more standard inductively coupled plasma setups as well as for validating models to optimize RF coupling.

Published

2021

11. Application of molecular convergent close-coupling cross sections in a collisional radiative model for the triplet system of molecular hydrogen

Author

Mark C. Zammit, D. Wünderlich, Stefan Briefi, Dmitry V. Fursa, Liam H. Scarlett, Igor Bray, and Ursel Fantz

Subjects

Low pressure plasma, Materials science, Acoustics and Ultrasonics, Plasma spectroscopy, Hydrogen molecule, Radiative transfer, Condensed Matter Physics, Close coupling, Molecular physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Abstract

Collisional radiative (CR) models for molecular hydrogen are of high relevance for performing qualitative and quantitative analysis of excited-state population densities measured in plasmas or predicting the dependence of plasma emission on parameter variations. Although the development of such models for H2 started decades ago, major uncertainties still exist regarding the most important set of input parameters, namely the cross sections for electron-impact excitation. The deviations between cross sections from different datasets are particularly pronounced in the energy region close to the threshold energy, strongly increasing the uncertainty of CR models applied to low-temperature plasmas. This paper presents experimental validation of a set of newly calculated non ro-vibrationally resolved electron-impact cross sections calculated for the triplet system of H2 using the molecular convergent close-coupling method in the adiabatic-nuclei formulation. These cross sections are implemented into a CR model based on the flexible solver Yacora. A first comparison of CR calculations with the different datasets to experimentally-determined population densities is performed at a planar ICP discharge for varying pressure (between 1 and 10 Pa) and RF power (between 700 and 1100 W). For the experimentally-accessible electron temperature and density range (2.5–10 eV and 1.8–3.3 × 1016 m−3, respectively), very good agreement between the model and experiment is obtained using the new data set, in contrast to previously used cross sections.

Published

2021

12. Spectroscopic investigations of the ion source at BATMAN upgrade

Author

Stefan Briefi, Ursel Fantz, and NNBI Team, Max Planck Institute for Plasma Physics, Max Planck Society

Subjects

Physics, Electron density, Upgrade, Line-of-sight, Spectrometer, Hydrogen, chemistry, Plasma parameters, chemistry.chemical_element, Field strength, Ion source, Computational physics

Abstract

The steady improvement of the analysis of atomic and molecular hydrogen emissivities together with the possibility to apply a high-resolution spectrometer motivated repeating at BATMAN Upgrade the detailed optical emission spectroscopy investigations performed at the BATMAN test facility in 2006. Although the test facility as a whole was upgraded, the RF-driven prototype source for the ITER NBI systems basically remained the same. The measurements were carried out in the first operation phase of BATMAN Upgrade i.e. in hydrogen in the volume operation mode of the negative ion source. The previously measured gas temperature of 1000 K in the driver, increasing to about 1200 K towards the grid is now determined to be 630 K in the whole source. Moreover, by evaluating now 12 rotational lines of the molecular Fulcher-α radiation instead of five, the presence of a two-temperature rotational distribution is demonstrated, revealing a hot ensemble with a temperature of about 4300 K. For the line of sight through the driver and the one parallel to the grid, the evaluation of the electron density and temperature showed similar values and trends as in the campaign of 2006. The third line of sight observes the expansion region and gives access, for the first time, to the plasma parameters in this region. Dependencies on the variation of the magnetic filter field strength and its topology are observed. The density ratio of atomic to molecular hydrogen is about 0.3 in all source regions, revealing no pronounced dependence on the filter field; however, due to the complex analysis procedure, the uncertainties are quite high for this parameter.

Published

2018

13. Study of the influence of magnetic field profile on plasma parameters in a simple mirror trap

Author

Mazzaglia, Maria, Castro, Giuseppe, Celona, Luigi, Gammino, Santo, Mascali, David, Miracoli, Rosalba, Naselli, Eugenia, Reitano, Riccardo, Stefan, Briefi, Torrisi, Giuseppe, and Ursel, Fantz

Subjects

010302 applied physics, Materials science, Plasma parameters, Theory and simulation, Plasma, 01 natural sciences, Electromagnetic radiation, Spectral line, Accelerator Physics, 010305 fluids & plasmas, Magnetic field, Trap (computing), symbols.namesake, Distribution function, Physics::Plasma Physics, 0103 physical sciences, symbols, Langmuir probe, Atomic physics, Instrumentation, Mathematical Physics

Abstract

This work presents the multiple diagnostics characterization of the plasma in an axis-symmetric simple mirror trap as a function of magnetic field profile (mirror ratios and magnetic field gradient), neutral gas pressure and microwave power. The simultaneous use of Optical Emission Spectroscopy, Langmuir Probe and X-ray diagnostics allows the characterization of the whole electron energy distribution function (EEDF), from a few eV to hundreds of keV. Results show non-linear behaviours under small variations of even one source parameter and strong influence of EEDF on the Bmin/BECR ratio. Benefit and next developments will be highlighted., Proceedings of the 23th Int. Workshop on ECR Ion Sources, ECRIS2018, Catania, Italy

Published

2018

14. Investigation of the RF efficiency of inductively coupled hydrogen plasmas at 1 MHz

Author

Stefan Briefi, J. Lettry, K. Nishida, S. Mattei, M. Q. Tran, D. Rauner, Akiyoshi Hatayama, Ursel Fantz, and Faircloth, D

Subjects

010302 applied physics, Coupling, Electron density, Materials science, Hydrogen, Plasma parameters, chemistry.chemical_element, Plasma, 01 natural sciences, 7. Clean energy, 010305 fluids & plasmas, chemistry, Inductively coupled plasma atomic emission spectroscopy, 0103 physical sciences, Atomic physics, Inductively coupled plasma, Inductively coupled plasma mass spectrometry

Abstract

The power requirements of RF heated sources for negative hydrogen ions in fusion are substantial, which poses strong demands on the generators and components of the RF circuit. Consequently, an increase of the RF coupling efficiency would be highly beneficial. Fundamental investigations of the RF efficiency in inductively coupled hydrogen and deuterium discharges in cylindrical symmetry are conducted at the lab experiment CHARLIE. The experiment is equipped with several diagnostics including optical emission spectroscopy and a movable floating double probe to monitor the plasma parameters. The presented investigations are performed in hydrogen at a varying pressure between 0.3 and 10 Pa, utilizing a conventional helical ICP coil driven at a frequency of 1MHz and a fixed power of 520W for plasma generation. The coupling efficiency is strongly affected by the variation in pressure, reaching up to 85% between 1 and 3 Pa while dropping down to only 50% at 0.3 Pa, which is the relevant operating pressure for negative hydrogen ion sources for fusion. Due to the lower power coupling, also the measured electron density at 0.3 Pa is only 5 . 10(16) m(-3), while it reaches up to 2.5 . 10(17) m(-3) with increasing coupling efficiency. In order to gain information on the spatially resolved aspects of RF coupling and plasma heating which are not diagnostically accessible, first simulations of the discharge by an electromagnetic Particle-In-Cell Monte Carlo collision method have been conducted and are compared to the measurement data. At 1 Pa, the simulated data corresponds well to the results of both axially resolved probe measurements and radially resolved emission profiles obtained via OES. Thereby, information regarding the radial distribution of the electron density and mean energy is provided, revealing a radial distribution of the electron density which is well described by a Bessel profile.

Published

2017

15. CERN’s Linac4 cesiated surface H− source

Author

M. Paoluzzi, D. Steyaert, N. David, Serge Mathot, Stefan Briefi, M. Haase, D. Fink, Alessandra Lombardi, Davide Aguglia, Marco Garlaschè, C. Machado, N. Thaus, M. O'Neil, R. Scrivens, I. Koszar, Roberto Guida, S. Mattei, Ursel Fantz, Alessandro Dallocchio, J. D. Hansen, A. Jones, Alexej Grudiev, G. Voulgarakis, E. Chaudet, Akiyoshi Hatayama, F. Di Lorenzo, Y. Coutron, P. Moyret, Sebastien Bertolo, U. Raich, Taneli Kalvas, K. Nishida, J. Lettry, Federico Roncarolo, A. Butterworth, Jean-Baptiste Lallement, Cristiano Mastrostefano, and Faircloth, Dan

Subjects

Nuclear physics, Large Hadron Collider, Materials science, ion sources, Proton, ta114, Aperture, Thermal emittance, Atomic physics, H- ions, Ion source, Beam (structure)

Abstract

Linac4 cesiated surface H− sources are routinely operated for the commissioning of the CERN’s Linac4 and on an ion source test stand. Stable current of 40-50 mA are achieved but the transmission through the LEBT of 80% was below expectations and triggered additional beam simulation and characterization. The H− beam profile is not Gaussian and emittance measurements are larger than simulation. The status of ongoing development work is described; 36 mA H− and 20 mA D− beams were produced with a 5.5 mm aperture cesiated surface ion source. The emittances measured at the test stand are presented. During a preliminary test, the Linac4 proton source delivered a total beam intensity of 70 mA (p, H2+, H3+). peerReviewed

Published

2017

16. Experimental investigation of plasma impedance in Linac4 H− source

Author

M. Haase, G. Voulgarakis, M. Paoluzzi, A. Jones, Akiyoshi Hatayama, A. Butterworth, Alexej Grudiev, Stefan Briefi, K. Nishida, J. Lettry, and S. Mattei

Subjects

Luminosity (scattering theory), Large Hadron Collider, Computer science, Plasma parameters, RF power amplifier, Particle accelerator, Input impedance, Plasma, computer.software_genre, Computational physics, law.invention, law, Operating system, Physics::Accelerator Physics, computer, Beam (structure)

Abstract

CERN ’s new particle accelerator Linac4 is part of the upgrade of the LHC accelerator chain. Linac4 is required to deliver 160 MeV H− beam to improve the beam brightness and luminosity in the Large Hadron Collider (LHC). The Linac4 H− source must deliver 40-50 mA, 45 keV H− beam in the RFQ acceptance. Since the RF power coupled to the H− source plasma is one of the important parameters that determines the quality of the H− beam, the experimental investigation of the dependence of the load impedance on the operational parameters is mandatory. In this study, we have measured the impedance of the H− source plasma varying the RF power coupled to the plasma and the condition of the hydrogen gas. Also, optical emission spectroscopy (OES) measurements have been carried out simultaneously with the impedance measurement in order to determine the plasma parameters. The determination of the plasma parameters allows us to compare the experimental results with the analytic model of the plasma parameters, which is useful to discuss the results from a physical point of view.CERN ’s new particle accelerator Linac4 is part of the upgrade of the LHC accelerator chain. Linac4 is required to deliver 160 MeV H− beam to improve the beam brightness and luminosity in the Large Hadron Collider (LHC). The Linac4 H− source must deliver 40-50 mA, 45 keV H− beam in the RFQ acceptance. Since the RF power coupled to the H− source plasma is one of the important parameters that determines the quality of the H− beam, the experimental investigation of the dependence of the load impedance on the operational parameters is mandatory. In this study, we have measured the impedance of the H− source plasma varying the RF power coupled to the plasma and the condition of the hydrogen gas. Also, optical emission spectroscopy (OES) measurements have been carried out simultaneously with the impedance measurement in order to determine the plasma parameters. The determination of the plasma parameters allows us to compare the experimental results with the analytic model of the plasma parameters, which is usef...

Published

2017

17. Influence of the cusp field on the plasma parameters of the Linac4 H- ion source

Author

S. Mattei, Stefan Briefi, Ursel Fantz, and J. Lettry

Subjects

Electron density, Materials science, Plasma parameters, RF power amplifier, Pulse duration, 020206 networking & telecommunications, 02 engineering and technology, 021001 nanoscience & nanotechnology, 7. Clean energy, Ion source, Magnet, 0202 electrical engineering, electronic engineering, information engineering, Electron temperature, Atomic physics, 0210 nano-technology, Excitation

Abstract

When the H− ion source of CERN’s Linac4 is operated in volume mode, a maximum of the extracted current is obtained at varying RF power. The power required for this maximum and its absolute value is strongly influenced by the cusp magnets installed at the source for electron confinement: without magnets, 15−20 mA are typically obtained at 20 kW whereas with magnets a factor of two more power is needed and 25−30 mA are achieved. In order to access the reasons behind the peaked performance with varying RF power and for determining the influence of the cusp field on the discharge, optical emission spectroscopy (OES) measurements of the atomic Balmer series and of the molecular Fulcher transition have been carried out. In all investigated cases, the gas temperature of the discharge has been virtually equal to the ambient temperature as the short discharge pulse length of 500 µs is not long enough for considerable heavy particle heating. When no cusp magnets are installed, the plasma parameters evaluated with the collisional radiative models Yacora H and Yacora H2 show a minimum in the electron temperature of 3.25 eV and a maximum in the electron density of 4×1019 m−3 and also in the vibrational excitation of the hydrogen molecule at 20 kW. Assessing the relevant production and destruction processes demonstrates that the H− yield is maximal at this point thereby explaining the optimum ion source performance. When the cusp magnets are applied, the same general trends are observed but the required RF power is a factor of two higher. The OES results indicate an optimum performance around 30 kW whereas the highest H− current is actually achieved around 40 kW. Furthermore, a higher H− yield is indicated without cusp magnets but a better ion source performance is observed with magnets. These differences can most likely be attributed to changing gradients in the plasma parameters which are not accessible by OES. Nevertheless, the obtained plasma parameters can be used as benchmark for RF coupling codes simulating the Linac4 ion source.

Published

2017

18. Simulation of the A–X and B–X transition emission spectra of the InCl molecule in low pressure plasmas

Author

Ursel Fantz and Stefan Briefi

Subjects

Radiation, Materials science, Plasma parameters, Transition dipole moment, Rotational temperature, Atomic and Molecular Physics, and Optics, Spectral line, Dipole, Wavelength, chemistry.chemical_compound, Indium halides, chemistry, Emission spectrum, Physics::Chemical Physics, Atomic physics, Spectroscopy

Abstract

Low pressure plasmas containing indium halides as radiators are discussed for lighting applications as an efficient alternative to mercury-containing fluorescent lamps. To gain insight into plasma parameters like the vibrational and rotational temperature of the molecule, the near UV emission spectra of the indium halides arising from the AΠ0+3→XΣ+1 and the BΠ13→XΣ+1 transitions are simulated. Such a simulation requires Franck–Condon factors and vibrationally resolved transition probabilities which are not available in the literature for InCl. Therefore, they have been calculated by solving the Schrodinger equation using the Born–Oppenheimer approximation. The values of the Franck–Condon factors and the transition probabilities are presented. For the A–X transition a good match of the simulated and measured spectra could be achieved but for the B–X transition neither the relative intensity nor the wavelength could be reproduced. This indicates that for the B state the values of the molecular constants, the potential curve and/or the electronic dipole transition moment of the B–X transition are inaccurate. Despite this mismatch the rotational and vibrational temperatures of the molecule can still be determined using the A–X transition.

Published

2014

19. Comparison of the B field dependency of plasma parameters of a weakly magnetized inductive and Helicon hydrogen discharge

Author

D. Rauner, P. Gutmann, Ursel Fantz, and Stefan Briefi

Subjects

010302 applied physics, Electron density, Hydrogen, Field (physics), Plasma parameters, chemistry.chemical_element, Electron, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Magnetic field, Helicon, chemistry, Physics::Plasma Physics, 0103 physical sciences, Electron temperature, Atomic physics

Abstract

The discharge properties of a weakly magnetized inductively coupled hydrogen discharge (operating pressure 1 Pa) are evaluated by using optical emission spectroscopy. The behaviour of the electron density n e, temperature T e and the density ratio of atomic to molecular hydrogen n H/ with varying magnetic field strength (up to 12 mT) is investigated. The results obtained from the OES measurements performed with a line of sight directed along the central axis of the cylindrical discharge vessel are compared to the case when the ICP antenna is replaced by a Nagoya-type-III Helicon antenna. In the ICP case, the electron temperature and density at the axis of the cylindrical discharge vessel decrease with increasing magnetic field due to the hindered radial electron diffusion. This results in a gradual transition from a homogeneous radial emission profile to a hollow profile with minimal emission in the discharge centre. Concerning the density ratio of atomic to molecular hydrogen, one obtains very high values of up to 0.32 at low B field and a decreasing behaviour with higher magnetic fields. For the Helicon case, the obtained values of n e and T e are virtually unaffected by the external magnetic field. Furthermore, a hollow radial emission profile is observed already at low B field strengths. In the Helicon setup one obtains an increasing trend for n H/ with a maximum of about 0.2 at 12 mT.

Published

2016

20. Alternative RF coupling configurations for H− ion sources

Author

P. Gutmann, Stefan Briefi, and Ursel Fantz

Subjects

Coupling, Chemistry, business.industry, RF power amplifier, 7. Clean energy, 01 natural sciences, Inductive coupling, 010305 fluids & plasmas, Magnetic field, Helicon, 0103 physical sciences, Optoelectronics, Helical antenna, Antenna (radio), Electric current, Atomic physics, 010306 general physics, business

Abstract

RF heated sources for negative hydrogen ions both for fusion and accelerators require very high RF powers in order to achieve the required H− current what poses high demands on the RF generators and the RF circuit. Therefore it is highly desirable to improve the RF efficiency of the sources. This could be achieved by applying different RF coupling concepts than the currently used inductive coupling via a helical antenna, namely Helicon coupling or coupling via a planar ICP antenna enhanced with ferrites. In order to investigate the feasibility of these concepts, two small laboratory experiments have been set up. The PlanICE experiment, where the enhanced inductive coupling is going to be investigated, is currently under assembly. At the CHARLIE experiment systematic measurements concerning Helicon coupling in hydrogen and deuterium are carried out. The investigations show that a prominent feature of Helicon discharges occurs: the so-called low-field peak. This is a local improvement of the coupling efficiency at a magnetic field strength of a few mT which results in an increased electron density and dissociation degree. The full Helicon mode has not been achieved yet due to the limited available RF power and magnetic field strength but it might be sufficient for the application of the coupling concept to ion sources to operate the discharge in the low-field-peak region.

Published

2015

21. Ways to improve the efficiency and reliability of radio frequency driven negative ion sources for fusion

Author

W. Kraus, Ursel Fantz, J. Doerfler, Stefan Briefi, and P. Gutmann

Subjects

Radio transmitter design, Physics, business.industry, RF power amplifier, Electrical engineering, Electric generator, Neutral beam injection, law.invention, Generator (circuit theory), Helicon, law, Radio frequency, Atomic physics, business, Instrumentation, Electrical efficiency

Abstract

Large RF driven negative hydrogen ion sources are being developed at IPP Garching for the future neutral beam injection system of ITER. The overall power efficiency of these sources is low, because for the RF power supply self-excited generators are utilized and the plasma is generated in small cylindrical sources ("drivers") and expands into the source main volume. At IPP experiments to reduce the primary power and the RF power required for the plasma production are performed in two ways: The oscillator generator of the prototype source has been replaced by a transistorized RF transmitter and two alternative driver concepts, a spiral coil, in which the field is concentrated by ferrites, which omits the losses by plasma expansion and a helicon source are being tested.

Published

2014

22. Initial Phase of a Large Atmospheric Plasmoid Generated above a Water Surface

Author

Stefan Briefi, Alexander Oswald, Roland Friedl, Martin Kammerloher, Johannes Kolbinger, and Ursel Fantz

Subjects

Physics, Nuclear and High Energy Physics, Atmospheric pressure, Initial phase, Electrode, Ball lightning, Plasmoid, Mechanics, Plasma, Condensed Matter Physics, Atmospheric sciences, Optical spectra

Abstract

A water plasmoid in atmospheric pressure air with an autonomous phase of ~500 ms is formed from a discharge above a water surface, which is powered only for 150 ms. The plasma ball has a diameter of ~20 cm and is often referred to as the ball lightning phenomena. High speed cameras and optical spectra are used for diagnostic purposes. An image of the initial phase reveals the formation of the plasma ball from the inner electrode with streamers above the water surface.

Published

2014

23. Note: Implementation of a cold spot setup for controlled variation of vapor pressures and its application to an InBr containing discharge lamp

Author

Stefan Briefi

Subjects

Gas-discharge lamp, Materials science, Absorption spectroscopy, Vapor pressure, Analytical chemistry, chemistry.chemical_element, Halide, Plasma, Low-pressure discharge, law.invention, chemistry.chemical_compound, Indium halides, chemistry, law, Instrumentation, Indium

Abstract

In order to allow for a systematic investigation of the plasma properties of discharges containing indium halides, which are proposed as an efficient alternative for mercury based low pressure discharge lamps, a controlled variation of the indium halide density is mandatory. This can be achieved by applying a newly designed setup in which a well-defined cold spot location is implemented and the cold spot temperature can be adjusted between 50 and 350 °C without influencing the gas temperature. The performance of the setup has been proved by comparing the calculated evaporated InBr density (using the vapor pressure curve) with the one measured via white light absorption spectroscopy.

Published

2013

24. Diagnostics of low-pressure discharges containing InBr studied for lighting applications

Author

Stefan Briefi and Ursel Fantz

Subjects

education.field_of_study, Argon, Chemistry, Plasma parameters, Population, Analytical chemistry, chemistry.chemical_element, Plasma, Effective radiated power, Condensed Matter Physics, Ionization, Atomic physics, education, Excitation, Electron ionization

Abstract

The utilization of InBr in low-pressure rare-gas plasmas for lighting applications may serve as an efficient alternative to hazardous mercury, which is used in common fluorescent lamps as a radiator. In order to perform systematic investigations of these discharges, diagnostic methods are required to gain insight into the relevant plasma parameters. This goal can be achieved by using white light absorption and optical emission spectroscopy supported by an extended corona model of the indium atom and a simulation of the relative intensity of the InBr emission. The set of diagnostic methods is exemplarily applied to measurements on an inductively coupled argon discharge at 100 W power with varying InBr content. The plasma parameters are derived and the processes determining their changes with varying InBr density are identified. Increasing the InBr density results in a decrease in Te but an increase in ne, which can be explained by considering the ionization and power balance. The relevant population processes for the rovibrational states of InBr are inelastic collisions with heavy particles with an increasing importance of electron impact excitation at a higher InBr density. The radiated power is maximal at a cold spot temperature between 210 and 220 °C as reabsorption occurs at a high InBr density.

Published

2013

25. Workshop on performance variations in H? ion sources 2012: PV H?12

Author

Roland Friedl, C. Wimmer, Martin P. Stockli, Ursel Fantz, Dan Faircloth, Damian King, Stefan Briefi, Dan Bollinger, Baoxi Han, Jacques Lettry, Werner Kraus, Katsuyoshi Tsumori, Mieko Kashiwagi, Robert F Welton, Olli Tarvainen, Hannu Koivisto, Yasuhiko Takeiri, and Akira Ando

Subjects

Engineering, Work (electrical), ta114, business.industry, Systems engineering, business, Engineering physics

Abstract

This paper briefly summarizes a workshop held in Jyvaskyla the day after NIBS’12. The half-day workshop aimed at globally capturing the issue of performance variations in H− sources. There was a focus on production facilities and facilities that work under production-like conditions, because there are often high expectations to be met.

Published

2013

26. Investigation of Helicon discharges as RF coupling concept of negative hydrogen ion sources

Author

Ursel Fantz and Stefan Briefi

Subjects

Argon, Helicon, chemistry, Hydrogen, Deuterium, Plasma parameters, RF power amplifier, chemistry.chemical_element, Plasma, Radio frequency, Atomic physics

Abstract

The ITER reference source for H− and D− requires a high RF input power (up to 90 kW per driver). To reduce the demands on the RF circuit, it is highly desirable to reduce the power consumption while retaining the values of the relevant plasma parameters namely the positive ion density and the atomic hydrogen density. Helicon plasmas are a promising alternative RF coupling concept but they are typically generated in long thin discharge tubes using rare gases and an RF frequency of 13.56 MHz. Hence the applicability to the ITER reference source geometry, frequency and the utilization of hydrogen/deuterium has to be proved. In this paper the strategy of the approach for using Helicon discharges for ITER reference source parameters is introduced and the first promising measurements which were carried out at a small laboratory experiment are presented. With increasing RF power a mode transition to the Helicon regime was observed for argon and argon/hydrogen mixtures. In pure hydrogen/deuterium the mode transition could not yet be achieved as the available RF power is too low. In deuterium a special feature of Helicon discharges, the socalled low field peak, could be observed at a moderate B-field of 3 mT.

Published

2013

27. Determination of discharge parameters via OES at the Linac4 H− ion source

Author

S. Mattei, D. Fink, J. Lettry, Stefan Briefi, and Ursel Fantz

Subjects

education.field_of_study, Materials science, Plasma parameters, Population, Analytical chemistry, Balmer series, 02 engineering and technology, Plasma, 021001 nanoscience & nanotechnology, 01 natural sciences, Ion source, symbols.namesake, Nuclear magnetic resonance, 0103 physical sciences, Plasma parameter, symbols, Plasma diagnostics, Emission spectrum, 010306 general physics, 0210 nano-technology, education, Instrumentation

Abstract

Optical emission spectroscopy (OES) measurements of the atomic Balmer series and the molecular Fulcher transition have been carried out at the Linac4 ion source in order to determine plasma parameters. As the spectroscopic system was only relatively calibrated, the data evaluation only yielded rough estimates of the plasma parameters (T(e) ≈ 1.2 eV, n(e) ≈ 1 × 10(19) m(-3), and n(H/)n(H2) ≈ 0.5 at standard operational parameters). The analysis of the Fulcher transition revealed a non-thermal "hockey-stick" rotational population of the hydrogen molecules. At varying RF power, the measurements at the on-axis line of sight (LOS) showed a peak in the rotational temperatures between 25 and 40 kW of RF power, whereas a steady decrease with power was observed at a tilted LOS, indicating the presence of strong plasma parameter gradients.

Published

2016

28. Linac4 H− ion sources

Author

E. Chaudet, Alessandro Dallocchio, A. Jones, D. C. Faircloth, D. Steyaert, N. David, G. Voulgarakis, Akiyoshi Hatayama, Davide Aguglia, D. Nisbet, P. Andersson, Richard Scrivens, Stefano Mattei, S. Bertolo, M. Haase, Serge Mathot, Alexej Grudiev, Stefan Briefi, Y. Coutron, C. Machado, T. Shibata, M. Paoluzzi, M. O’Neil, C. Mastrostefano, D. Fink, Roberto Guida, Ursel Fantz, A. Butterworth, N. Thaus, Alessandra Lombardi, P. Moyret, J. D. Hansen, Marco Garlaschè, K. Nishida, Jean-Baptiste Lallement, J. Lettry, J. G. Alessi, and I. Koszar

Subjects

010302 applied physics, Physics, Large Hadron Collider, Physics::Instrumentation and Detectors, Electron, 01 natural sciences, Ion source, Linear particle accelerator, 010305 fluids & plasmas, Nuclear physics, 0103 physical sciences, Cavity magnetron, Physics::Accelerator Physics, Thermal emittance, Beam emittance, Instrumentation, Beam (structure)

Abstract

CERN's 160 MeV H(-) linear accelerator (Linac4) is a key constituent of the injector chain upgrade of the Large Hadron Collider that is being installed and commissioned. A cesiated surface ion source prototype is being tested and has delivered a beam intensity of 45 mA within an emittance of 0.3 π ⋅ mm ⋅ mrad. The optimum ratio of the co-extracted electron- to ion-current is below 1 and the best production efficiency, defined as the ratio of the beam current to the 2 MHz RF-power transmitted to the plasma, reached 1.1 mA/kW. The H(-) source prototype and the first tests of the new ion source optics, electron-dump, and front end developed to minimize the beam emittance are presented. A temperature regulated magnetron H(-) source developed by the Brookhaven National Laboratory was built at CERN. The first tests of the magnetron operated at 0.8 Hz repetition rate are described.

Published

2016

29. Correction factors for saturation effects in white light and laser absorption spectroscopy for application to low pressure plasmas

Author

Ursel Fantz, C. Wimmer, and Stefan Briefi

Subjects

Physics, Tunable diode laser absorption spectroscopy, Laser diode, Absorption spectroscopy, business.industry, Condensed Matter Physics, Laser, Spectral line, law.invention, Semiconductor laser theory, Optics, law, Atomic physics, Saturation (chemistry), business, Absorption (electromagnetic radiation)

Abstract

In white light absorption spectroscopy, the broadening of the absorption signal due to the apparatus profile of the spectrometer may lead to an underestimation of the determined density as one measures an apparent optical depth. This is in particular true for high optical depth where saturation effects of the transmitted intensity occur. Provided that the line profile of the absorption line is known, the apparent optical depth effect can be accounted for by introducing a correction factor. The impact of the saturation and the approach of considering the effect are demonstrated for argon and indium lines in low pressure plasmas where correction factors of one order of magnitude or even higher are reached very easily. For the indium line, the hyperfine splitting has been taken into account. In laser absorption, the line profile is resolved. However, the weak but rather broad background emission of the laser diode can cause a saturation signal at the photo diode resulting also in an underestimation of the de...

Published

2012

30. Correlation of size, velocity, and autonomous phase of a plasmoid in atmosphere with the dissipated energy

Author

Stefan Briefi, Ursel Fantz, and Roland Friedl

Subjects

Atmosphere, Chemistry, Phase (matter), General Physics and Astronomy, Plasmoid, Power factor, Plasma, Dissipation, Atomic physics, Capacitance, Voltage

Abstract

The visual properties of a large plasmoid rising from a water container into the air for up to 450 ms are brought into correlation with the total energy dissipated into the system, and, in particular, with the energy used for plasma generation. The latter parameters are deduced from the time-resolved discharge current and voltage of the capacitor bank which is used as energy supply. By varying the experimental parameters, the energy dissipated to the system varies between 5 kJ and 30 kJ from which 10% to 30% is transferred to the plasma. Clear correlations are obtained for the size of the plasmoid changing from 15 cm to 35 cm in width, the ascent velocity ranging from 1 m/s to 2 m/s, and the rising height for which up to 85 cm is measured. For the relation of the autonomous phase with the energy transferred to the plasma, two trends are observed: 450 ms duration is achieved in maximum with the present setup being almost independent on the electrode gap, the voltage-on time, the water conductivity, or the type of salt dissolved in the water. On the other hand, an almost linear dependence is obtained by changing the capacitance.

Published

2015

31. Generation of an atmospheric plasmoid from a water discharge: An analysis of the dissipated energy

Author

Ursel Fantz, Stefan Briefi, S. Kalafat, and Roland Friedl

Subjects

Atmospheric pressure, Chemistry, General Physics and Astronomy, Plasmoid, Mechanics, Plasma, Dissipation, Capacitance, law.invention, Capacitor, Plate electrode, Physics::Plasma Physics, law, Voltage

Abstract

A plasmoid in air at atmospheric pressure of about 20 cm in diameter and up to 500 ms duration is generated from a water discharge which is powered for a short time period by a capacitor bank. The analysis of the electrical circuit and the comparison with experimental values show that the energy dissipated into the system is given by the conventional equation for discharging capacitors. The resistance of the system is governed by the resistances of the water reservoir, the plasma, and the plasma-water transition, which are represented as one time-averaged resistance in the equation. Thus, the dissipated energy can be influenced by the energy available (capacitance and voltage), the voltage-on time, the conductivity of the water, the electrode gap and the size of the container (plate electrode) within the experimental boundaries. An estimation of the energy channels for a discharge at standard conditions revealed that the dominant part of the energy is dissipated into the water reservoir. About 25% of the energy is dissipated directly into the plasmoid and is available for plasma formation, plasma kinetics and chemical processes.

Published

2013

32. Simulation of the A–X and B–X transition emission spectra of the InBr molecule for diagnostics in low-pressure plasmas

Author

Stefan Briefi, Ursel Fantz, Institut für Physik, Universität Augsburg [Augsburg], and Max-Planck-Institut für Plasmaphysik [Garching] (IPP)

Subjects

Acoustics and Ultrasonics, Absorption spectroscopy, Plasma parameters, Vapor pressure, 33.20.Lg, 33.20.Vq, Population, 33.70.Fd, 02 engineering and technology, 01 natural sciences, symbols.namesake, 0103 physical sciences, Emission spectrum, Physics::Chemical Physics, education, 52.70.Kz, 010302 applied physics, Arrhenius equation, education.field_of_study, Chemistry, 33.70.Ca, Rotational temperature, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, symbols, Atomic physics, 0210 nano-technology, Ground state

Abstract

Inductively coupled low-pressure discharges containing InBr have been investigated spectroscopically. In order to obtain plasma parameters such as the vibrational and rotational temperature of the InBr molecule, the emission spectra of the and the transitions have been simulated. The program is based on the molecular constants and takes into account vibrational states up to v = 24. The required Franck–Condon factors and vibrationally resolved transition probabilities have been computed solving the Schrödinger equation using the Born–Oppenheimer approximation. The ground state density of the InBr molecule in the plasma has been determined from absorption spectra using effective transition probabilities for the A–X and B–X transition according to the vibrational population. The obtained densities agree well with densities derived from an Arrhenius type vapour pressure equation.

Published

2011

33. Determination of the rotational population of H2 and D2 including high-N states in low temperature plasmas via the Fulcher-α transition

Author

D. Rauner, Stefan Briefi, and Ursel Fantz

Subjects

010302 applied physics, education.field_of_study, Radiation, Materials science, Hydrogen, Population, chemistry.chemical_element, Rotational temperature, Rotational–vibrational spectroscopy, 01 natural sciences, Diatomic molecule, Atomic and Molecular Physics, and Optics, Ion, Deuterium, chemistry, 0103 physical sciences, Rotational spectroscopy, Atomic physics, 010306 general physics, education, Spectroscopy

Abstract

Vibrational and rotational excitation of the hydrogen molecule can significantly affect molecular reaction rates in low pressure low temperature plasmas, for example for the creation of H − / D − ions via the dissociative attachment process. In general, the rotational population in these discharges is known to be non-thermal with an overpopulation of states with high rotational quantum number N. In contrast to a sophisticated direct measurement of the rotational distribution in the X Σ g + 1 , v = 0 state, it is demonstrated that the determination can also be carried out up to high-N levels rather easily via optical emission spectroscopy utilizing the Fulcher-α transition of H2 and D2. The measured rotational populations can be described with a two-temperature distribution where the cold part reflects the population according to the gas temperature of the discharge. This has been verified by using the emission of the second positive system of nitrogen as independent gas temperature diagnostic. The hot part where the rotational temperature reaches several thousand Kelvin arises most probably from recombinative desorption of hydrogen at the discharge vessel wall where parts of the binding energy are converted into rotational excitation. Neglecting the hot population – what is often done when using the Fulcher-α transition as gas temperature diagnostic – can lead to a strong overestimation of Tgas. No fundamental differences in the rotational distributions between hydrogen and deuterium have been found, only the hot rotational temperature is smaller for D2 indicating an isotope-dependency of the recombinative desorption process.

34. RF power transfer efficiency of inductively coupled low pressure H 2 and D 2 discharges

Author

Stefan Briefi, Ursel Fantz, and D. Rauner

Subjects

Materials science, Hydrogen, Plasma parameters, RF power amplifier, chemistry.chemical_element, Plasma, Condensed Matter Physics, 01 natural sciences, 7. Clean energy, 010305 fluids & plasmas, chemistry, Ionization, 0103 physical sciences, Maximum power transfer theorem, Electron temperature, Inductively coupled plasma, Atomic physics, 010306 general physics

Abstract

The RF power transfer efficiency and the relevant power absorption mechanisms of inductively heated hydrogen and deuterium plasmas are investigated in the low-pressure region between 0.25 and 10 Pa. The discharges are generated in a cylindrical vessel via a helical coil applying a frequency of 1 MHz and delivered RF powers up to 800 W. The power transfer efficiency η is quantified by a subtractive method that relies on the measurement of the delivered RF power and of the RF current through the plasma coil both with and without discharge operation. By means of optical emission spectroscopy and electrical probe measurements, the key plasma parameters are obtained. For both H2 and D2, the relative behavior of the power transfer efficiency is well comparable, which increases with increasing delivered RF power and describes a maximum at pressures between 1 and 3 Pa where more than of the provided power are absorbed by the plasma. The observed relative dependencies of η on the operational parameters are found to be well explained by an analytical approach that considers the power absorption by the plasma via evaluating the RF plasma conductivity based on the measured plasma parameters. At the parameters present, non-collisional stochastic heating of electrons has to be considered for pressures , while collisional heating dominates at higher pressure. Molecular dissociation is found to have a significant influence on the power transfer efficiency of light molecular discharges. The direct comparison of H2 and D2 identifies the higher atomic density in deuterium to cause a systematically increased power transfer efficiency due to an increased ionization rate in the present electron temperature region.