Multi-dipolar plasmas for uniform processing: physics, design and performance

Lacoste, A.; Lagarde, T.; Béchu, Stéphane; Arnal, Y.; Pelletier, Jacques

doi:10.1088/0963-0252/11/4/307

Cited by 89 publications

(91 citation statements)

References 13 publications

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“…Up to 2016, an aluminum disk shaped metallization was locally performed by using the DMW (Distributed Microwave Plasmas), a technology developed by LPSC [18]. The crystal surface preparation and metal deposition were thus performed by a sequential plasma process consisting in two steps of reactive plasma cleaning followed by plasma-assisted sputtering.…”

Section: B Detector Processing and Pulse Signal Readoutmentioning

confidence: 99%

A large area diamond-based beam tagging hodoscope for ion therapy monitoring

et al. 2018

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Abstract-. The MoniDiam project is part of the French national collaboration CLaRyS (Contrôle en Ligne del'hAdronthérapie par RaYonnements Secondaires) for on-line monitoring of hadron therapy. It relies on the imaging of nuclear reaction products that is related to the ion range. The goal here is to provide large area beam detectors with a high detection efficiency for carbon or proton beams giving time and position measurement at 100 MHz count rates (beam tagging hodoscope). High radiation hardness and intrinsic electronic properties make diamonds reliable and very fast detectors with a good signal to noise ratio. Commercial Chemical Vapor Deposited (CVD) polycrystalline, heteroepitaxial and monocrystalline diamonds were studied. Their applicability as a particle detector was investigated using α and β radioactive sources, 95 MeV/u carbon ion beams at GANIL and 8.5 keV X-ray photon bunches from ESRF. This facility offers the unique capability of providing a focused (~1 µm) beam in bunches of 100 ps duration, with an almost uniform energy deposition in the irradiated detector volume, therefore mimicking the interaction of single ions. A signal rise time resolution ranging from 20 to 90 ps rms and an energy resolution of 7 to 9% were measured using diamonds with aluminum disk shaped surface metallization. This enabled us to conclude that polycrystalline CVD diamond detectors are good candidates for our beam tagging hodoscope development. Recently, double-side stripped metallized diamonds were tested using the XBIC (X Rays Beam Induced Current) set-up of the ID21 beamline at ESRF which permits us to evaluate the capability of diamond to be used as position sensitive detector. The final detector will consist in a mosaic arrangement of double-side stripped diamond sensors read out by a dedicated fast-integrated electronics of several hundreds of channels. therapy. Ions deposit a large fraction of the dose at the end of their path, in the Bragg peak. Compared to conventional X-ray radiotherapy, hadron therapy allows a more efficient dose delivery in the tumor, with a reduction of the dose deposited in the nearby healthy organs. The conformation of the deposited dose to the tumor volume is provided by distributing Bragg peaks in this volume, either spot by spot, or by means of passive scattering and energy degradation. However, since multiple sources of uncertainty on the ion range may cause deviations from the planned dose distribution [1], online control of the ion range is desired in order to reduce safety margins and optimize the ballistic advantage of ion therapy.During an irradiation with ion beams, nuclear reactions occur for part of the projectiles along their path in the patient body, and photons in the range 1-10 MeV are emitted almost isotropically within much less than a picosecond after the reactions. It has been shown experimentally that the longitudinal distribution of such prompt-gamma production is highly correlated to the primary ion range

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Section: B Detector Processing and Pulse Signal Readoutmentioning

confidence: 99%

A large area diamond-based beam tagging hodoscope for ion therapy monitoring

et al. 2018

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“…The microwave power from a 2 kW generator at 2.45 GHz (Sairem V R ) is divided in 12 channels, so that the power injected into each cell can be adjusted independently, allowing a good controllability of the uniformity profile. 36 Each ECR cell includes a water cooled permanent magnet that provides a localized magnetic field of 875 Gauss necessary for electron cyclotron resonance. A water cooled magnetic filter (see Fig.…”

Section: Methodsmentioning

confidence: 99%

“…34 However, filament discharges are incompatible with most of the equipments used for micro-and nanoelectronic industry. Recently, a new type of ECR plasma source was build, namely, the multidipolar ECR, [36][37][38] which allows one to produce an easy scalable plasma source in various configurations, free of magnetic field in plasma volume, operating even below 10 mTorr. From the point of view of industrial applications, a negative ion plasma source that can provide the following characteristics is desirable: no contamination by filaments, no density jumps; negligible magnetic field in plasma volume; a density ratio of negative ion to electron higher than 50 (as to make it possible to bias the substrate positively without affecting the plasma potential, V pl , and to avoid overheating by electrons 33,34 ); stable operation at low pressure with no plasma potential drift; 34 good controllability of ion species and high etching rates.…”

Section: Introductionmentioning

confidence: 99%

High electronegativity multi-dipolar electron cyclotron resonance plasma source for etching by negative ions

Stamate

Draghici

2012

Journal of Applied Physics

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A large area plasma source based on 12 multi-dipolar ECR plasma cells arranged in a 3 × 4 matrix configuration was built and optimized for silicon etching by negative ions. The density ratio of negative ions to electrons has exceeded 300 in Ar/SF6 gas mixture when a magnetic filter was used to reduce the electron temperature to about 1.2 eV. Mass spectrometry and electrostatic probe were used for plasma diagnostics. The new source is free of density jumps and instabilities and shows a very good stability for plasma potential, and the dominant negative ion species is F−. The magnetic field in plasma volume is negligible and there is no contamination by filaments. The etching rate by negative ions measured in Ar/SF6/O2 mixtures was almost similar with that by positive ions reaching 700 nm/min.

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“…[3]. Our new reactor, named ATOS, which has been operational since October 2007, will be briefly presented here.…”

Section: Principle and Descriptionmentioning

confidence: 99%

Microcrystalline silicon films and solar cells deposited at high rate by Matrix Distributed Electron Cyclotron Resonance (MDECR) plasma

Kroely

Ram

Bulkin

et al. 2010

Phys. Status Solidi (c)

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The latest results obtained in a new promising Matrix Distributed Electron Cyclotron Resonance (MDECR) reactor for the deposition of microcrystalline silicon (μc‐Si:H) films and cells are reported in this article. The reactor is presented with a focus on the importance and the difficulties of temperature measurements. The unique properties of this high density plasma allowed us to demonstrate high deposition rates of 28 Å/s. The chemical composition of the MDECR material has been compared to a standard material and in particular, the effect of the oxygen level will be discussed. The installation of a load‐lock allowed a reduction of the oxygen con‐tamination by a factor of 10. Lower microwave powers helped to improve the electrical properties of the material. So far, the cell performance unfortunately seems decoupled from these successive optimizations of the film quality, and stayed limited (© 2010 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

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Multi-dipolar plasmas for uniform processing: physics, design and performance

Cited by 89 publications

References 13 publications

A large area diamond-based beam tagging hodoscope for ion therapy monitoring

A large area diamond-based beam tagging hodoscope for ion therapy monitoring

High electronegativity multi-dipolar electron cyclotron resonance plasma source for etching by negative ions

Microcrystalline silicon films and solar cells deposited at high rate by Matrix Distributed Electron Cyclotron Resonance (MDECR) plasma

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