Your search keyword '"Biri, S."' showing total 9 results

1. Space-resolved electron density and temperature evaluation by x-ray pinhole camera method in an ECR plasma.

Author

Finocchiaro, G., Naselli, E., Mishra, B., Biri, S., Mazzaglia, M., Pidatella, A., Rácz, R., Torrisi, G., and Mascali, D.

Subjects

PINHOLE cameras, PHOTON counting, CYCLOTRON resonance, PLASMA astrophysics, ELECTRON distribution, SPHEROMAKS, RADIOACTIVE decay, ELECTRON density

Abstract

X-ray emission characterization provides valuable insights about electron cyclotron resonance (ECR) plasmas. In principle, space-resolved spectroscopic techniques can be used to reveal spatial distributions of electron density and temperature. In the PANDORA (Plasma for Astrophysics, Nuclear Decay Observation, and Radiation for Archaeometry) project framework, and within the collaboration between the Atomki and INFN-LNS laboratories, we developed a high-resolution full-field x-ray pinhole setup. This setup incorporates advanced analysis techniques for single photon counted imaging in high dynamical range mode, enabling x-ray imaging and space-resolved spectroscopy at high spatial and energy resolution (560 μ m and 242 eV @ 8.1 keV, respectively). Here, we introduce an innovative technique for quantitatively evaluating the local electron density and temperature of plasma, as the first application of such a method in an ECR setup. Specifically, we examine an argon plasma heated by 200 W microwave power at 14 GHz. Our analysis includes a retrospective comparison with past x-ray data collected from other ECR ion source setups. Our findings clearly reveal the formation of a plasmoid–halo structure within the plasma chamber, characterized by a dense and hot plasma almost totally enclosed inside the ECR magnetic iso-surface (the plasmoid). This plasmoid exhibits nearly uniform distribution of electron density and temperature, with only gentle gradients of both the parameters toward its edges. Inside the halo, x-ray emission is minimal or even negligible. Notably, cusp structures correspond to magnetic branches where deconfined electrons impinge upon the plasma chamber walls and endplates. The average values of temperature and density measured inside the plasmoid are 12.44 ± 1.84 keV and (1.66 ± 0.15) × 10 17 m − 3 , respectively. [ABSTRACT FROM AUTHOR]

Published

2024

2. A novel numerical tool to study electron energy distribution functions of spatially anisotropic and non-homogeneous ECR plasmas.

Author

Mishra, B., Pidatella, A., Biri, S., Galatà, A., Naselli, E., Rácz, R., Torrisi, G., and Mascali, D.

Subjects

DISTRIBUTION (Probability theory), ENERGY function, CYCLOTRON resonance, ARGON plasmas, X-ray spectra, HOT carriers, ELECTRON distribution

Abstract

A numerical tool for analyzing spatially anisotropic electron populations in electron cyclotron resonance (ECR) plasmas has been developed, using a trial-and-error electron energy distribution function (EEDF) fitting method. The method was tested on space-resolved warm electrons in the energy range 2 – 20 keV , obtained from self-consistent simulations modeling only electron dynamics in ECR devices, but lacked real-world validation. For experimentally benchmarking the method, we attempted to use the tested EEDF to numerically reproduce experimental x-ray emission spectrum measured from an argon plasma. The analysis revealed a stronger contribution from hot electrons than expected, and this information will be fed back to simulation models to generate more realistic data. Subsequent application of the numerical tool to the improved simulation data can result in continuous EEDFs that reflect the nature of charge distributions in anisotropic ECR plasmas. These functions can be also applied to electron-dependent reactions, in order to reproduce experimental results, like those concerning space-dependent Kα emissions. [ABSTRACT FROM AUTHOR]

Published

2021

3. On the Formation Mechanism of Modified Fullerenes in the Two-Chamber Configuration of the Bio-Nano ECRIS.

Author

Uchida, T., Rácz, R., Kawabata, T., Muramatsu, M., Kitagawa, A., Biri, S., and Yoshida, Y.

Subjects

FULLERENES, CYCLOTRON resonance, ION sources, ELECTRON density, ELECTRON plasma

Abstract

Recently, we reported a fullerene modification using neutral-neutral or neutral-ion collision reactions in the two-chamber configuration of the Bio-Nano electron cyclotron resonance ion source (ECRIS). In our methodology, modified fullerenes can be synthesized in vapor-phase in an ECR plasma, or on a surface of a plasma chamber, and can be characterized by on-line mass spectrometric analysis of the ECRIS beam, or by off-line analyses (e.g. time-of-flight mass spectrometry, liquid chromatography mass spectrometry, etc.). So far, we have successfully synthesized a modified C70 with iron (Fe) and chlorine (Cl) atoms using two individual plasmas; Fe-Cl plasma and C70 plasma. In a subsequent experiment, shown in this study, we investigated the ion/electron density distributions in the plasma chamber by using electrostatic probe method. We correlated these results with the off-line synthesized material investigations and also with plasma electron simulations in order to collect more information on the mechanism of the synthesis process. [ABSTRACT FROM AUTHOR]

Published

2018

4. X-ray pinhole camera setups used in the Atomki ECR Laboratory for plasma diagnostics.

Author

Rácz, R., Biri, S., Pálinkás, J., Mascali, D., Castro, G., Caliri, C., Romano, F. P., and Gammino, S.

Subjects

*CYCLOTRON resonance, *PROTON-induced X-ray emission, *SPATIAL analysis (Statistics), *ELECTRONS, *X-ray spectra

Abstract

Imaging of the electron cyclotron resonance (ECR) plasmas by using CCD camera in combination with a pinhole is a non-destructive diagnostics method to record the strongly inhomogeneous spatial density distribution of the X-ray emitted by the plasma and by the chamber walls. This method can provide information on the location of the collisions between warm electrons and multiple charged ions/atoms, opening the possibility to investigate the direct effect of the ion source tuning parameters to the plasma structure. The first successful experiment with a pinhole X-ray camera was carried out in the Atomki ECR Laboratory more than 10 years ago. The goal of that experiment was to make the first ECR X-ray photos and to carry out simple studies on the effect of some setting parameters (magnetic field, extraction, disc voltage, gas mixing, etc.). Recently, intensive efforts were taken to investigate now the effect of different RF resonant modes to the plasma structure. Comparing to the 2002 experiment, this campaign used wider instrumental stock: CCD camera with a lead pinhole was placed at the injection side allowing X-ray imaging and beam extraction simultaneously. Additionally, Silicon Drift Detector (SDD) and High Purity Germanium (HPGe) detectors were installed to characterize the volumetric X-ray emission rate caused by the warm and hot electron domains. In this paper, detailed comparison study on the two X-ray camera and detector setups and also on the technical and scientific goals of the experiments is presented. [ABSTRACT FROM AUTHOR]

Published

2016

5. Conclusions from recent pionic—atom experiments.

Author

Gotta, D., Amaro, F., Anagnostopoulos, D. F., Biri, S., Covita, D. S., Gorke, H., Gruber, A., Hennebach, M., Hirtl, A., Ishiwatari, T., Indelicato, P., Jensen, Th., Le Bigot, E.-O., Marton, J., Nekipelov, M., dos Santos, J. M. F., Schlesser, S., Schmid, Ph., Simons, L. M., and Strauch, Th.

Subjects

ATOMS, CYCLOTRONS, CYCLOTRON resonance, ION traps, ENERGY-band theory of solids, QUANTUM electrodynamics, NUCLEAR physics

Abstract

The most recent pionic—hydrogen experiment marks the completion of a whole series of measurements, the main goal of which was to provide conclusive data on pion—nucleon interaction at threshold for comparison with calculations from Chiral perturbation theory. The precision achieved for hadronic shift and broadening of 0.2% and 2%, respectively, became possible by comprehensive studies of cascade effects in hydrogen and other light exotic atoms including results from the last years of LEAR operation. In order to obtain optimum conditions for the Bragg crystal spectrometer, the cyclotron trap II has been used to provide a suitable X—ray source. To characterize the bent crystal spectrometer, the cyclotron trap has been modified to operate as an electron—cyclotron resonance source, which produces with high intensity narrow X-ray transitions in the few keV range originating from highly charged ions. [ABSTRACT FROM AUTHOR]

Published

2008

6. Review on heavy ion radiotherapy facilities and related ion sources (invited).

Author

Kitagawa, A., Fujita, T., Muramatsu, M., Biri, S., and Drentje, A. G.

Subjects

NUCLEAR physics instruments, HEAVY ion radiotherapy, ELECTRON cyclotron resonance sources, ION sources, PLASMA radiation, QUANTUM electrodynamics, CYCLOTRON resonance

Abstract

Heavy ion radiotherapy awakens worldwide interest recently. The clinical results obtained by the Heavy Ion Medical Accelerator in Chiba at the National Institute of Radiological Sciences in Japan have clearly demonstrated the advantages of carbon ion radiotherapy. Presently, there are four facilities for heavy ion radiotherapy in operation, and several new facilities are under construction or being planned. The most common requests for ion sources are a long lifetime and good stability and reproducibility. Sufficient intensity has been achieved by electron cyclotron resonance ion sources at the present facilities. [ABSTRACT FROM AUTHOR]

Published

2010

7. Two-chamber configuration of Bio-Nano electron cyclotron resonance ion source for fullerene modification.

Author

Uchida, T., Rácz, R., Muramatsu, M., Kato, Y., Kitagawa, A., Biri, S., and Yoshida, Y.

Subjects

ION sources, ELECTRON cyclotron resonance sources, CHLORINE, CYCLOTRON resonance, FULLERENES

Abstract

We report on the modification of fullerenes with iron and chlorine using two individually controllable plasmas in the Bio-Nano electron cyclotron resonance ion source (ECRIS). One of the plasmas is composed of fullerene and the other one is composed of iron and chlorine. The online ion beam analysis allows one to investigate the rate of the vapor-phase collisional modification process in the ECRIS, while the offline analyses (e.g., liquid chromatography-mass spectrometry) of the materials deposited on the plasma chamber can give information on the surface-type process. Both analytical methods show the presence of modified fullerenes such as fullerene-chlorine, fullerene-iron, and fullerene-chlorine-iron. [ABSTRACT FROM AUTHOR]

Published

2016

8. Status of the Bio-Nano electron cyclotron resonance ion source at Toyo University.

Author

Uchida, T., Minezaki, H., Ishihara, S., Muramatsu, M., Rácz, R., Asaji, T., Kitagawa, A., Kato, Y., Biri, S., Drentje, A. G., and Yoshida, Y.

Subjects

ELECTRON cyclotron resonance sources, CYCLOTRON resonance, ION sources, NUCLEAR physics instruments, PARTICLES (Nuclear physics), ION-molecule collisions

Abstract

In the paper, the material science experiments, carried out recently using the Bio-Nano electron cyclotron resonance ion source (ECRIS) at Toyo University, are reported. We have investigated several methods to synthesize endohedral C60 using ion-ion and ion-molecule collision reaction in the ECRIS. Because of the simplicity of the configuration, we can install a large choice of additional equipment in the ECRIS. The Bio-Nano ECRIS is suitable not only to test the materials production but also to test technical developments to improve or understand the performance of an ECRIS. [ABSTRACT FROM AUTHOR]

Published

2014

9. Fullerene-rare gas mixed plasmas in an electron cyclotron resonance ion source.

Author

Asaji, T., Ohba, T., Uchida, T., Minezaki, H., Ishihara, S., Racz, R., Muramatsu, M., Biri, S., Kitagawa, A., Kato, Y., and Yoshida, Y.

Subjects

FULLERENES, ELECTRON cyclotron resonance sources, ION sources, PLASMA radiation, NUCLEAR physics instruments, CYCLOTRON resonance

Abstract

A synthesis technology of endohedral fullerenes such as Fe@C60 has developed with an electron cyclotron resonance (ECR) ion source. The production of N@C60 was reported. However, the yield was quite low, since most fullerene molecules were broken in the ECR plasma. We have adopted gas-mixing techniques in order to cool the plasma and then reduce fullerene dissociation. Mass spectra of ion beams extracted from fullerene-He, Ar or Xe mixed plasmas were observed with a Faraday cup. From the results, the He gas mixing technique is effective against fullerene destruction. [ABSTRACT FROM AUTHOR]

Published

2014