1,100 research outputs found
Modeling and simulation of a beam emission spectroscopy diagnostic for the ITER prototype neutral beam injector
A test facility for the development of the Neutral Beam Injection system for
ITER is under construction at Consorzio RFX. It will host two experiments:
SPIDER, a 100 keV H-/D- ion RF source, and MITICA, a prototype of the full
performance ITER injector (1 MV, 17 MW beam). A set of diagnostics will monitor
the operation and allow to optimize the performance of the two prototypes. In
particular, Beam Emission Spectroscopy will measure the uniformity and the
divergence of the fast particles beam exiting the ion source and travelling
through the beam line components. This type of measurement is based on the
collection of the H{\alpha}/D{\alpha} emission resulting from the interaction
of the energetic particles with the background gas. A numerical model has been
developed to simulate the spectrum of the collected emissions in order to
design this diagnostic and to study its performance. The paper describes the
model at the base of the simulations and presents the modeled
spectra in the case of MITICA experiment.Comment: 4 pages, 5 figures. Contributed paper for the HTPD 2014 conference.
Accepted manuscrip
Test of ID carbon-carbon composite prototype tiles for the SPIDER diagnostic calorimeter
Additional heating will be provided to the thermonuclear fusion experiment ITER by injection of neutral beams from accelerated negative ions. In the SPIDER test facility, under construction at Consorzio RFX in Padova (Italy), the production of negative ions will be studied and optimised. To this purpose the STRIKE (Short-Time Retractable Instrumented Kalorimeter Experiment) diagnostic will be used to characterise the SPIDER beam during short operation (several seconds) and to verify if the beam meets the ITER requirement regarding the maximum allowed beam non-uniformity (below \ub110%). The most important measurements performed by STRIKE are beam uniformity, beamlet divergence and stripping losses. The major components of STRIKE are 16 1D-CFC (Carbon matrix-Carbon Fibre reinforced Composite) tiles, observed at the rear side by a thermal camera. The requirements of the 1D CFC material include a large thermal conductivity along the tile thickness (at least 10 times larger than in the other directions); low specific heat and density; uniform parameters over the tile surface; capability to withstand localised heat loads resulting in steep temperature gradients. So 1D CFC is a very anisotropic and delicate material, not commercially available, and prototypes are being specifically realised. This contribution gives an overview of the tests performed on the CFC prototype tiles, aimed at verifying their thermal behaviour. The spatial uniformity of the parameters and the ratio between the thermal conductivities are assessed by means of a power laser at Consorzio RFX. Dedicated linear and non-linear simulations are carried out to interpret the experiments and to estimate the thermal conductivities; these simulations are described and a comparison of the experimental data with the simulation results is presented
Modeling and design of a BES diagnostic for the negative ion source NIO1
Consorzio RFX and INFN-LNL are building a flexible small ion source (NIO1)
capable of producing about 130 mA of H- ions accelerated at 60 KeV. Aim of the
experiment is to test and develop the instrumentation for SPIDER and MITICA,
the prototypes respectively of the negative ion sources and of the whole
neutral beam injectors which will operate in the ITER experiment. As SPIDER and
MITICA, NIO1 will be monitored with Beam Emission Spectroscopy (BES), a
non-invasive diagnostic based on the analysis of the spectrum of the
emission produced by the interaction of the energetic ions with the background
gas. Aim of BES is to monitor direction, divergence and uniformity of the ion
beam. The precision of these measurements depends on a number of factors
related to the physics of production and acceleration of the negative ions, to
the geometry of the beam and to the collection optics. These elements were
considered in a set of codes developed to identify the configuration of the
diagnostic which minimizes the measurement errors. The model was already used
to design the BES diagnostic for SPIDER and MITICA. The paper presents the
model and describes its application to design the BES diagnostic in NIO1.Comment: 3 pages, 3 figures. Contributed paper for the ICIS 2013 conference.
Accepted manuscrip
A Comparison of a Brain-Computer Interface and an Eye Tracker: Is There a More Appropriate Technology for Controlling a Virtual Keyboard in an ALS Patient?
The ability of people affected by amyotrophic lateral sclerosis (ALS), muscular dystrophy or spinal cord injuries to physically interact with the environment, is usually reduced. In some cases, these patients suffer from a syndrome known as locked-in syndrome (LIS), defined by the patient’s inability to make any move-ment but blinks and eye movements. Tech communication systems available for people in LIS are very limited, being those based on eye-tracking and brain-computer interface (BCI) the most useful for these patients. A comparative study between both technologies in an ALS patient is carried out: an eye tracker and a visual P300-based BCI. The purpose of the study presented in this paper is to show that the choice of the technology could depend on user´s preference. The evaluation of performance, workload and other subjective measures will allow us to determine the usability of the systems. The obtained results suggest that, even if for this patient the BCI technology is more appropriate, the technology should be always tested and adapted for each user.Universidad de Málaga. Campus de Excelencia Internacional AndalucĂa Tech
First Beam Characterization by Means of Emission Spectroscopy in the NIO1 Experiment
The NIO1 experiment hosts a flexible RF H- ion source, developed by INFN-LNL
and Consorzio RFX to improve the present concepts for the production and
acceleration of negative ions. The source is also used to benchmark the
instrumentation dedicated to the ITER neutral beam test facility. Many
diagnostics are installed in NIO1 to characterize the source and the extracted
negative ion beam. Among them, Beam Emission Spectroscopy (BES) has been used
in NIO1 to measure the divergence and the uniformity of the beam, together with
the fraction of beam ions which was neutralized inside the acceleration system.
The diagnostic method is based on the analysis of the Doppler shifted
photons emitted by the fast beam particles and collected along a
line of sight. The article presents the experimental setup and the analysis
algorithms of the BES diagnostic, together with a discussion of the first
measurements and of their correlation with the operational parameters.Comment: 3 pages, 2 figures. Contributed paper for the ICIS 2017 conference.
Accepted manuscript of a published pape
Characterization of Cs-free negative ion production in the ion source SPIDER by Cavity Ring-Down Spectroscopy
The Neutral beam Injectors of the ITER experiment will be based on negative
ion sources for the generation of beams composed by 1 MeV H/D particles. The
prototype of these sources is currently under testing in the SPIDER experiment,
part of the Neutral Beam Test Facility of Consorzio RFX, Padua, Italy. Among
the targets of the experimentation in SPIDER, it is of foremost importance to
maximize the beam current density extracted from the source acceleration
system. The SPIDER operating conditions can be optimized thanks to a Cavity
Ring-down Spectroscopy diagnostic, which is able to give line-integrated
measurements of negative ion density in proximity of the acceleration system
apertures. Regarding the diagnostic technique, this work presents a phenomenon
of drift in ring down time measurements, which develops in a time scale of few
hours. This issue may significantly affect negative ion density measurements
for plasma pulses of 1 h duration, as required by ITER. Causes and solutions
are discussed. Regarding the source performance, this paper presents how
negative ion density is influenced by the RF power used to sustain the plasma,
and by the magnetic filter field present in SPIDER to limit the amount of
co-extracted electrons. In this study, SPIDER was operated in hydrogen and
deuterium, in Cs-free conditions.Comment: 9 pages, 5 figures. Accepted manuscript of a published articl
Numerical and experimental investigations of a microwave interferometer for the negative ion source SPIDER
The electron density close to the extraction grids and the co-extracted
electrons represent a crucial issue when operating negative ion sources for
fusion reactors. An excessive electron density in the plasma expansion region
can indeed inhibit the negative ion production and introduce potentially
harmful electrons in the accelerator. Among the set of plasma and beam
diagnostics proposed for SPIDER upgrade, a heterodyne microwave (mw)
interferometer at 100 GHz is being explored as a possibility to measure
electron density in the plasma extraction region. The major issue in applying
this technique in SPIDER is the poor accessibility of the probing microwave
beam through the source metal walls and the long distance of 4 m at which mw
modules should be located outside the vacuum vessel. Numerical investigations
in a full-scale geometry showed that the power transmitted through the plasma
source apertures was sufficient for the microwave module sensitivity. An
experimental proof-of-principle of the setup was then performed. The microwave
system was tested on an experimental full-scale test-bench mimicking SPIDER
viewports accessibility constraints, including the presence of a SPIDER-like
plasma. The outcome of first tests revealed that, despite the geometrical
constraints, in certain conditions, the electron density measurements are
possible. The main issue arises from decoupling the one-pass signal from
spurious multipaths generated by mw beam reflections, requiring signal cross
correlation analysis. These preliminary tests demonstrate that despite the 4 m
distance between the mw modules and the presence of metal walls, plasma density
measurement is possible when the 80-mm diameter ports are available. In this
contribution, we discuss the numerical simulations, the preliminary
experimental tests and suggest design upgrades of the interferometric setup to
enhance signal transmission
Electron Density and Temperature in NIO1 RF Source Operated in Oxygen and Argon
The NIO1 experiment, built and operated at Consorzio RFX, hosts an RF
negative ion source, from which it is possible to produce a beam of maximum 130
mA in H- ions, accelerated up to 60 kV. For the preliminary tests of the
extraction system the source has been operated in oxygen, whose high
electronegativity allows to reach useful levels of extracted beam current. The
efficiency of negative ions extraction is strongly influenced by the electron
density and temperature close to the Plasma Grid, i.e. the grid of the
acceleration system which faces the source. To support the tests, these
parameters have been measured by means of the Optical Emission Spectroscopy
diagnostic. This technique has involved the use of an oxygen-argon mixture to
produce the plasma in the source. The intensities of specific Ar I and Ar II
lines have been measured along lines of sight close to the Plasma Grid, and
have been interpreted with the ADAS package to get the desired information.
This work will describe the diagnostic hardware, the analysis method and the
measured values of electron density and temperature, as function of the main
source parameters (RF power, pressure, bias voltage and magnetic filter field).
The main results show that not only electron density but also electron
temperature increase with RF power; both decrease with increasing magnetic
filter field. Variations of source pressure and plasma grid bias voltage appear
to affect only electron temperature and electron density, respectively.Comment: 7 pages 4 figures. Contributed paper for the NIBS 2016 conference.
Accepted manuscrip
Negative ion density in the ion source SPIDER in Cs free conditions
The SPIDER experiment, operated at the Neutral Beam Test Facility of
Consorzio RFX, Padua, hosts the prototype of the H-/D- ion source for the ITER
neutral beam injectors. The maximization of the ion current extracted from the
source and the minimization of the amount of co-extracted electrons are among
the most relevant targets to accomplish. The Cavity Ring-Down Spectroscopy
diagnostic measures the negative ion density in the source close to the
acceleration system, so as to have feedback information to optimize the source
parameters and to maximize the amount of negative ions that can be extracted at
optimal beam divergence. This work shows how the magnetic filter field and the
bias currents, present in SPIDER to limit the amount of co-extracted electrons
and the electron-ion stripping reactions, affect the density of negative ions
available for extraction. Moreover, the influence of the extraction process on
the density of negative ions available for extraction is also presented. In
this study SPIDER was operated in hydrogen and deuterium in Cs-free conditions,
therefore negative ions were mostly produced by reactions in the plasma volume.Comment: 13 pages, 8 figures. Preprint of a published pape
Development and first operation of a Cavity Ring Down Spectroscopy diagnostic in the negative ion source SPIDER
The Neutral Beam Injectors of the ITER experiment will rely on negative ion
sources to produce 16.7 MW beams of H/D particles accelerated at 1 MeV. The
prototype of these sources was built and is currently operated in the SPIDER
experiment (Source for the Production of Ions o Deuterium Extracted from an RF
plasma), part of the Neutral Beam Test Facility of Consorzio RFX, Padua. In
SPIDER, the H-/D- ion source is coupled to a three grids 100 kV acceleration
system. One of the main targets of the experimentation in SPIDER is to
uniformly maximize the extracted current density; to achieve this it is
important to study the density of negative ions available in proximity of the
ion acceleration system. In SPIDER, line-integrated measurements of negative
ion density are performed by a Cavity Ring Down Spectroscopy (CRDS) diagnostic.
Its principle of operation is based on the absorption of the photons of a laser
beam pulse by H-/D- photo-detachment; the absorption detection is enhanced by
trapping the laser pulse in an optical cavity, containing the absorbing medium
(i.e. negative ions). The paper presents and discusses the CRDS diagnostic
setup in SPIDER, including the first measurements of negative ion density,
correlated to the main source parameters.Comment: 5 pages, 7 figures. Contributer paper for the HTPD 2020 conference.
Accepted manuscrip
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