Your search keyword '"Ichikawa, M."' showing total 15 results

1. Study of beamlets extracted from a multi-aperture and five-stage acceleration system.

Author

Kashiwagi, M., Kisaki, M., Saquilayan, G. Q., Kojima, A., Hiratsuka, J., Ichikawa, M., Shimabukuro, Y., Murayama, M., and Tobari, H.

Subjects

BEAM optics, ION beams, SPACE charge, ANIONS, HEATING load, MAGNETIC fields

Abstract

A beam optics study using the ITER-relevant high intense negative ion beams, such as 1 MeV, 200 A/m2, has been performed experimentally and analytically using a multi-aperture and five-stage accelerator. Initially, multi-beamlets generated from this accelerator were deflected in various directions due to the magnetic field and space charge repulsion between beams and showed various divergences. These had limited the pulse length and the beam energy. Compensation methods of the beamlet deflections have worked effectively and contributed to achieving the ITER requirement, the divergence angle of <7 mrad, and the deflection angle of <1 mrad for 1 MeV beam. The beam pulse has been gradually extended from 1 to 100 s and is now going to a longer pulse based on these results. One of the remaining issues is to understand and suppress peripheral components of the beam, namely, the halo, and to reduce the local heat loads observed around the aperture edge. This halo component has been successfully distinguished from the beam core by using a newly developed beam emittance measurement system for high intense beams. By combining this measured beam emittance and the beam simulation, it was clarified for the first time that the halo components are generated in an area of 1 mm width from the aperture edge. [ABSTRACT FROM AUTHOR]

Published

2022

2. Experimental and numerical investigation on the asymmetry of the current density extracted through a plasma meniscus in negative ion accelerator.

Author

Denizeau, S, Aprile, D, Fubiani, G, Taccogna, F, Minelli, P, Ichikawa, M, Hiratsuka, J, Kashiwagi, M, Kojima, A, and Chitarin, G

Subjects

ANIONS, ION accelerators, PLASMA beam injection heating, ION sources, CURRENT distribution, NEUTRAL beams

Abstract

In multi-beamlet negative ion accelerators for neutral beam injectors, the transverse magnetic field necessary for suppressing the co-extracted electrons induces a deflection of the negative ion beamlets that must be corrected. For the design, particle-tracing simulation codes are used to compute ion trajectories and optical properties of the beamlets in the acceleration stage. In these codes, uniform boundary conditions are normally assumed for the ion current density distribution at the surface (called meniscus), where negative ions are extracted from the plasma and form beamlets, which are accelerated across the apertures of the accelerator grids. Recently, experimental campaigns dedicated to the accurate measurement of the beamlet deflection in the acceleration phase revealed higher deflection than foreseen by simulations. In this work, we demonstrate that an agreement with the experimental data can be obtained by incorporating in the numerical simulations a non-radially symmetric distribution of the ion current density extracted across the meniscus surface. In the first part, the asymmetry of the ion current density at the meniscus is studied in an empirical way, by analysing and fitting the experimental results obtained with different operating parameters. In the second part, we show that the ion current asymmetry estimated by this procedure is well consistent with the flow pattern of H− ions calculated in the meniscus zone using a detailed particle in cell (PIC) model of the ion source in the presence of transverse magnetic field. [ABSTRACT FROM AUTHOR]

Published

2020

3. Analysis of the cesium distribution in the JT-60SA negative ion sources for steady long-pulse operation.

Author

Yoshida, M., Oohara, W., Ichikawa, M., Hiratsuka, J., Saquilayan, G. Q., Umeda, N., Kojima, A., and Kashiwagi, M.

Subjects

ION sources, ANIONS, CESIUM ions, CESIUM, ION bombardment, NEUTRAL beams, PLASMA production

Abstract

To realize stable negative ion beams for 100 s required in the neutral beam injector of JT-60SA, a physical model to control cesium (Cs) distribution inside the negative ion source has been developed in order to maintain the stable negative ion production at the plasma grid (PG) surface with Cs. In this work, to quantitatively evaluate Cs coverage on the PG, a three-dimensional Cs transportation code was introduced to consider the spatial Cs distribution in the source. The spatial temperature distribution of the chamber wall was also introduced in this model. As a result, the reasonable variation of the Cs coverage for 100 s was obtained, compared to that in the initial model. Based on the modified model, the operational temperature of the chamber wall was proposed to be less than 60 °C to suppress the desorption of Cs in the chamber wall and to sustain the stable negative ion production. In addition, it was also suggested that a slightly higher wall temperature before the operation leads to a decrease in the amount of Cs stored at the chamber wall, resulting in suppression of Cs consumption in the ion source. [ABSTRACT FROM AUTHOR]

Published

2020

4. Achievement of high power and long pulse negative ion beam acceleration for JT-60SA NBI.

Author

Hiratsuka, J., Kashiwagi, M., Ichikawa, M., Umeda, N., Saquilayan, G. Q., Tobari, H., Watanabe, K., Kojima, A., and Yoshida, M.

Subjects

ANIONS, ION beams, ION accelerators, ELECTROSTATIC accelerators, ACCELERATION (Mechanics), PLASMA beam injection heating

Abstract

Long pulse acceleration of hydrogen negative ion beams with the power density over 70 MW/m2 and the pulse length over 100 s has been demonstrated for the first time by using a multi-aperture 3-stage accelerator. Such long pulse acceleration was achieved by integrating the design of beam optics and voltage holding capability to meet the requirements of JT-60SA. By using the newly designed accelerator for JT-60SA, voltage holding at 500 kV with beam acceleration was stably sustained even after 5 g of cesium was seeded, and heat load on each acceleration grid was reduced below the allowable level for long pulse, less than 5% of total acceleration power. As a result, 500 keV, 154 A/m2 for 118 s beam acceleration was achieved, which satisfies the requirement of the negative ion source for JT-60SA. This pulse length of such high-power density beams is longest in the world. In addition, the result contributes to the long pulse acceleration of multi-stage electrostatic accelerators, such as 1 MeV negative ion accelerator for ITER. [ABSTRACT FROM AUTHOR]

Published

2020

5. Complete Compensation of Criss-cross Deflection in a Negative Ion Accelerator by Magnetic Technique.

Author

Aprile, Daniele, Agostinetti, P., Baltador, C., Denizeau, S., Hiratsuka, J., Ichikawa, M., Kashiwagi, M., Kojima, A., Marconato, N., Pimazzoni, A., Sartori, E., Serianni, G., Veltri, P., Yoshida, M., and Chitarin, G.

Subjects

ION accelerators, ANIONS, MAGNETIC deflection, PERMANENT magnets, CURRENT density (Electromagnetism)

Abstract

During 2016, a joint experimental campaign was carried out by QST and Consorzio RFX on the Negative Ion Test Stand (NITS) at the QST Naka Fusion Institute, Japan, with the purpose of validating some design solutions adopted in MITICA, which is the full-scale prototype of the ITER NBI, presently under construction at Consorzio RFX, Padova, Italy. The main purpose of the campaign was to test a novel technique, for suppressing the beamlet criss-cross magnetic deflection. This new technique, involving a set of permanent magnets embedded in the Extraction Grid, named Asymmetric Deflection Compensation Magnets (ADCM), is potentially more performing and robust than the traditional electrostatic compensation methods. The results of this first campaign confirmed the effectiveness of the new magnetic configuration in reducing the criss-cross magnetic deflection. Nonetheless, contrary to expectations, a complete deflection correction was not achieved. By analyzing in detail the results, we found indications that a physical process, taking place just upstream of the plasma grid, was giving an important contribution to the final deflection of the negative ion beam. This process appears to be related to the drift of negative ions inside the plasma source, in the presence of a magnetic field transverse to the extraction direction, and results in a non-uniform ion current density extracted at the meniscus. Therefore, the numerical models adopted in the design were improved by including this previously disregarded effect, so as to obtain a much better matching with the experimental results. Based on the results of the first campaign, new permanent magnets were designed and installed on the Extraction Grid of NITS. A second QST-Consorzio RFX joint experimental campaign was then carried out in 2017, demonstrating the complete correction of the criss-cross deflection and confirming the validity of the novel magnetic configuration and of the hypothesis behind the new models. This contribution presents the results of the second joint experimental campaign on NITS along with the overall data analysis of both campaigns, and the description of the improved models. A general picture is given of the relation among magnetic field, beam energy, meniscus non-uniformity and beamlet deflection, constituting a useful database for the design of future machines. [ABSTRACT FROM AUTHOR]

Published

2018

6. Evaluation of the Temperature Dependence of the Cesium Deposition on the Plasma Grid in the JT-60SA Negative Ion Source.

Author

Yoshida, M., Oohara, W., Ichikawa, M., Hiratsuka, J., Umeda, N., Kojima, A., and Kashiwagi, M.

Subjects

CESIUM, ANIONS, ION sources, IONIZATION (Atomic physics), QUARTZ crystal microbalances

Abstract

In order to evaluate deposition of cesium (Cs) in the plasma grid (PG) and investigate the origin of the gradual degradation of the negative ion current in a 100 s long pulsed operation in the JT-60SA negative ion source, Cs behavior in the source is model. To do this, Cs adsorption/desorption coefficient with a wide range of temperature is experimentally measured by a surface ionization detector and a quartz crystal microbalance. As a result, both of the adsorption and desorption are drastically varied at temperature range from room temperature to 100 °C. Based on these data, the model calculates the amounts of the Cs mass in the chamber wall and PG. The calculation result shows that, in the operation, an increase of temperature in the chamber wall (Twall) causes the evaporation of the huge amount of Cs in it. This leads to over pilling-up of Cs in the PG and the slight degradation of the negative ion production. Therefore, it is found that the constant temperature operation is needed to sustain the thickness of the Cs monolayer in the PG, and the Twall is desired to be less than 60 °C to suppress the evaporation of Cs in the chamber wall. According to this model, it is showed that there are many combinations of the temperatures to achieve it with low Cs consumption. [ABSTRACT FROM AUTHOR]

Published

2018

7. Determination of the meniscus shape of a negative ion beam from an experimentally obtained beam profile.

Author

Ichikawa, M., Kojima, A., Chitarin, G., Agostinetti, P., Aprile, D., Baltador, C., Barbisan, M., Delogu, R., Hiratsuka, J., Marconato, N., Nishikiori, R., Pimazzoni, A., Sartori, E., Serianni, G., Tobari, H., Umeda, N., Veltri, P., Watanabe, K., Yoshida, M., and Antoni, V.

Subjects

*MENISCUS (Liquids), *ANIONS, *ION beams, *PHYSICS experiments, *PLASMA density

Abstract

In order to understand the physics mechanism of a negative ion extraction in negative ion sources, an emission surface of the negative ions around an aperture at a plasma grid, so-called a meniscus, has been analyzed by an inverse calculation of the negative ion trajectory in a two dimensional beam analysis code. In this method, the meniscus is defined as the final position of the negative ion trajectories which are inversely calculated from the measured beam profile to the plasma grid. In a case of the volume-produced negative ions, the calculated meniscus by the inverse calculation was similar to that obtained in conventional beam simulation codes for positive ion extractions such as BEAMORBT and SLACCAD. The negative ion current density was uniform along the meniscus. This indicates that the negative ions produced in the plasma are transported to the plasma grid uniformly as considered in the transportation of the positive ions. However, in a surface production case of negative ions, where the negative ions are generated near the plasma grid with lower work function by seeding cesium, the current density in the peripheral region of the meniscus close to the plasma grid surface was estimated to be 2 times larger than the center region, which suggested that the extraction process of the surfaceproduced negative ions was much different with that for the positive ions. Because this non-uniform profile of the current density made the meniscus shape strongly concave, the beam extracted from the peripheral region could have a large divergence angle, which might be one of origins of so-called beam halo. This is the first results of the determination of the meniscus based on the experiment, which is useful to improve the prediction of the meniscus shape and heat loads based on the beam trajectories including beam halo. [ABSTRACT FROM AUTHOR]

Published

2017

8. Experimental Validation of an Innovative Deflection Compensation Method in a multi-Beamlet Negative-Ion Accelerator.

Author

Chitarin, G., Kojima, A., Agostinetti, P., Aprile, D., Baltador, C., Hiratsuka, J., Ichikawa, M., Marconato, N., Sartori, E., Serianni, G., Veltri, P., Yoshida, M., Kashiwagi, M., Hanada, M., and Antoni, V.

Subjects

ION accelerators, ANIONS, MAGNETIC fields, HYDROGEN ions, ION sources

Abstract

An innovative magnetic configuration called ADCM (Asymmetric Deflection Compensation Magnets) has been recently proposed for the cancellation of the "criss-cross" deflection of ion trajectories in multi-beamlet negative ion accelerators. Such undesired deflection occurs due to the transverse magnetic field, which is necessary for the suppression of co-extracted electrons. In view of the application of this concept to the ITER Heating Neutral Beam Injector, the new configuration has been experimentally tested for the first time in 2016, in the framework of a research collaboration between Consorzio RFX and QST. [ABSTRACT FROM AUTHOR]

Published

2017

9. Long pulse and high power density H- ion beam acceleration for ITER.

Author

Umeda, N., Hiratsuka, J., Kojima, A., Ichikawa, M., Yoshida, M., Yamanaka, H., Tobari, H., Watanabe, K., and Kashiwagi, M.

Subjects

POWER density, ION beams, ACCELERATION (Mechanics), ANIONS, PLASMA temperature

Abstract

A high power density and a long pulse negative ion beam accelerator has been developed in QST to realize the ITER neutral beam accelerator. A main target was the H- ion beam acceleration up to 1 MeV with 200 A/m² for 60 s. After the achievement of 1 MeV at a short pulse, the pulse length has been gradually extended by modifications of grid configurations to suppress grid heat loads due to negative ions and electrons. However, the beam energy was limited up to 0.7 MeV at 60 s operation. One issue was an unstable negative ion production for a long time due to arcing and excess temperature rise of a plasma grid for optimum negative ion production. To suppress arcing, a cathode filament shape was modified. The plasma grid was modified to have a large heat capacitance in order to suppress temperature rise for 60 s operation at high discharge power required for 1 MeV operation. Another issue is to optimize beam optics more precisely. Fine tuning of the 1st acceleration stage was carried to improve beam optics for high current density beam. With these modifications, high power density beam acceleration of 0.97 MeV, 190 A/m² has been achieved for 60 s. This is the first long pulse acceleration of ITER class high power density beam. [ABSTRACT FROM AUTHOR]

Published

2017

10. Benchmark of 3D multi-Beamlet Numerical Models for the Optics Design of Negative Ion Accelerators.

Author

Chitarin, G., Agostinetti, P., Aprile, D., Baltador, C., Hiratsuka, J., Ichikawa, M., Kojima, A., Kashiwagi, M., Marconato, N., Sartori, E., Serianni, G., and Veltri, P.

Subjects

ANIONS, TESTING laboratories, ION accelerators, MAGNETIC fields

Abstract

The optics design of the multi-beamlet negative ion accelerator for MITICA has been verified by means of specific experiments in the NITS test facility at the QST lab, employing a scaled-down configuration having the same features as the accelerator of MITICA and ITER HNB. The experiments confirmed the validity of the accelerator design. However it was found that, in the presence of transverse magnetic field in the ion extraction stage, the ion beamlet deflection in numerical simulations was somehow underestimated with respect to the beamlet deflection inferred from thermal images of a CFC target exposed to the negative ion beam. A detailed benchmark, using also another (completely independent) numerical model of the accelerator, has allowed the identification of possible origins of the differences. [ABSTRACT FROM AUTHOR]

Published

2018

11. Development of the negative ion beams relevant to ITER and JT-60SA at Japan Atomic Energy Agency.

Author

Hanada, M., Kojima, A., Tobari, H., Nishikiori, R., Hiratsuka, J., Kashiwagi, M., Umeda, N., Yoshida, M., Ichikawa, M., Watanabe, K., Yamano, Y., and Grisham, L. R.

Subjects

PARTICLE beam weapons, ANIONS, PARTICLE beams, THERMONUCLEAR fusion, CONTROLLED fusion

Abstract

In order to realize negative ion sources and accelerators to be applicable to International Thermonuclear Experimental Reactor and JT-60 Super Advanced, a large cesium (Cs)-seeded negative ion source and a multi-aperture and multi-stage electric acceleration have been developed at Japan Atomic Energy Agency (JAEA). Long pulse production and acceleration of the negative ion beams have been independently carried out. The long pulse production of the high current beams has achieved 100 s at the beam current of 15 A by modifying the JT-60 negative ion source. The pulse duration time is increased three times longer than that before the modification. As for the acceleration, a pulse duration time has been also extended two orders of magnitudes from 0.4 s to 60 s. The developments of the negative ion source and acceleration at JAEA are well in progress towards the realization of the negative ion sources and accelerators for fusion applications. [ABSTRACT FROM AUTHOR]

Published

2016

12. Time evolution of negative ion profile in a large cesiated negative ion source applicable to fusion reactors.

Author

Yoshida, M., Hanada, M., Kojima, A., Kashiwagi, M., Umeda, N., Hiratsuka, J., Ichikawa, M., Watanabe, K., Grisham, L. R., Tsumori, K., and Kisaki, M.

Subjects

NUCLEAR fusion, CESIUM electron tubes, ANIONS, CESIUM oxide, CONTROLLED fusion

Abstract

To understand the physics of the cesium (Cs) recycling in the large Cs-seeded negative ion sources relevant to ITER and JT-60SA with ion extraction area of 45-60 cm × 110-120 cm, the time evolution of the negative ion profile was precisely measured in JT-60SA where the ion extraction area is longitudinally segmented into 5. The Cs was seeded from the oven at 180 °C to the ion source. After 1 g of Cs input, surface production of the negative ions appeared only in the central segment where a Cs nozzle was located. Up to 2 g of Cs, the negative ion profile was longitudinally expanded over full ion extraction area. The measured time evolution of the negative ion profile has the similar tendency of distribution of the Cs atoms that is calculated. From the results, it is suggested that Cs atom distribution is correlated with the formation of the negative ion profile. [ABSTRACT FROM AUTHOR]

Published

2016

13. Improving a negative ion accelerator for next generation of neutral beam injectors: Results of QST-Consorzio RFX collaborative experiments.

Author

Chitarin, G., Kojima, A., Aprile, D., Agostinetti, P., Barbisan, M., Denizeau, S., Ichikawa, M., Hiratsuka, J., Kashiwagi, M., Marconato, N., Pimazzoni, A., Sartori, E., Serianni, G., Veltri, P., and Yoshida, M.

Subjects

*PLASMA beam injection heating, *ANIONS, *ION accelerators, *NEUTRAL beams, *PHENOMENOLOGICAL theory (Physics), *MAGNETIC ions

Abstract

• Joint experimental campaigns carried out in QST lab in Naka, Ibaraki, Japan. • Full compensation of magnetic criss-cross deflection of beamlets obtained. • Non-uniform extraction assumed for interpreting the experimental results. • Numerical simulations can reproduce the experimental results with good accuracy. In the framework of the collaboration between Consorzio RFX (Padova, Italy) and QST (Naka, Japan) two experimental campaigns have been organized on the Negative Ion Test Stand (NITS) in Naka, employing an ITER-like multi-beamlet configuration. These campaigns were aimed at compensating for the undesired magnetic deflection of the ion beam. The experiments have clarified the influence of operating parameters on the optical properties of the ion beam. The physical phenomena acting on the optics have been investigated, in particular the effect of an asymmetry of the ion current density at meniscus. Comparisons with simulations have been made and the modeling has been improved consequently. During the second experimental campaign, a perfect compensation of the ion deflection has been achieved. [ABSTRACT FROM AUTHOR]

Published

2019

14. Analysis on acceleration of DT-mixed ion beams in a negative ion accelerator for a DT-mixed Neutral Beam Injector.

Author

Kojima, A., Kashiwagi, M., Matsuda, S., Hanada, M., Hayashi, T., Ichikawa, M., Hiratsuka, J., Nishikiori, R., Umeda, N., Tobari, H., and Watanabe, K.

Subjects

*ACCELERATION (Mechanics), *DEUTERIUM compounds, *NEUTRAL beams, *TRITIUM, *ANIONS, *BEAM optics, *BEAM injection

Abstract

In order to reduce the tritium inventory in a fuel circulation system in fusion plants, a possibility of deuterium-tritium (DT) mixed neutral beam injectors with DT negative ion beams has been investigated by analyzing the beam optics of the DT-mixed negative ion beams for the first time. In a two-dimensional beam analysis, DT-mixed ion beams could be accelerated regardless of the DT current mixing ratio (T/D) from the identical acceleration geometry with the identical applied voltages by adjusting total space charge for the D and T components. However, in a three-dimensional beam analysis including magnetic fields, the DT-mixed ion beams were separated due to a mass dependence of the beam deflection by orthogonal magnetic fields of an electron suppression and transverse filter fields for negative ion production. In the case of the beamline for ITER, which requires beam deflection angle within ±1 mrad, the operational range for the DT-mixed ion beams was found to be the DT current mixing ratio of 0.7-1.5 and beam energy of 0.9-1.0 MeV. Although the operational range was not wide, the DT-mixed beam was found to be feasible in terms of the beam acceleration. These analyses also contribute to the study of the acceleration of other mixed ion beams such as impurity or heavy ions, which are useful techniques for diagnostic beams. [ABSTRACT FROM AUTHOR]

Published

2017

15. Benchmark of beam acceleration codes on a high voltage negative ion accelerator for fusion with a new hypothesis on the beam meniscus.

Author

Denizeau, S., Aprile, D., Agostinetti, P., Veronese, F., Patton, T., Pimazzoni, A., Hiratsuka, J., Ichikawa, M., Saquilayan, G.M., Kojima, A., Kashiwagi, M., and Chitarin, G.

Subjects

*ION accelerators, *ANIONS, *HIGH voltages, *BEAM optics, *ION sources, *DEFLECTION (Mechanics), *PLASMA beam injection heating, *ION beams

Abstract

• Experimental campaign on MTF carried out in QST lab in Naka, Ibaraki, Japan. • Opera, SLACCAD, COMSOL, EAMCC3D correctly predict beam divergence. • Semi-empirical Opera model with current density asymmetry correctly predicts the beam deflection. • COMSOL and EAMCC3D slightly underestimate heat loads on the grids. It is a widely recognized phenomenon that, in negative ion sources for NBI, the magnetic fields in the source cause an asymmetry of the current density at the meniscus, which affects the beam optics. In order to achieve a more realistic estimation of the negative ion beam optics, the ion current density profile at the beamlet meniscus is sometimes assumed to be non-symmetric with respect to the beamlet axis. The new hypothesis tested in this paper is an empirical law obtained by recent investigations on a similar Kamaboko ion source, which relates this asymmetry to the magnetic field strength at the meniscus and to the power injected in the ion source. For the first time this hypothesis is used to directly and correctly predict the value of the beamlet deflection. The MeV ion source Test Facility (MTF) is a high voltage negative ion beam accelerator dedicated to fusion experiments in QST, Naka, Ibaraki, Japan. MTF can be operated as a three- or five-stage multi-aperture accelerator with a configuration and beam energy comparable to the future ITER NBI. In 2019, experiments were conducted on MTF aiming at accelerating a H- beam with high energy and good optics for a long duration of the beam (around 100 s). These experiments allowed to measure the beamlet divergence and deflection as well as the heat loads due to particle impinging on the accelerator grids, over a wide range of operating parameters. The predictions of several beam simulation codes (Opera, COMSOL, SLACCAD, EAMCC3D) have been compared to the experimental measurements, which allows to obtain a good agreement in terms of beam optics and a fair agreement in terms of heat loads. [ABSTRACT FROM AUTHOR]

Published

2021