Your search keyword '"R. Kataura"' showing total 8 results

1. Stopping power measurement for proton therapy by combining proton radiography and X-ray CT

Author

R. Kataura, T. Izumikawa, T. Konno, and T. Kawasaki

Subjects

Nuclear and High Energy Physics, Instrumentation

Published

2022

2. Development of slow control system for the Belle II ARICH counter

Author

T. Sumiyoshi, P. Križan, M. Yonenaga, Rok Dolenec, H. Kindo, K. Ogawa, S. Nishida, T. Kumita, K. Hataya, Y. Yusa, R. Kataura, T. Kobayashi, Makoto Tabata, H. Kawai, Luka Santelj, Ichiro Adachi, S. Iori, Hidekazu Kakuno, R. Pestotnik, Samo Korpar, S. Ogawa, Shuichi Iwata, and M. Mrvar

Subjects

Physics, Nuclear and High Energy Physics, Pixel, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, Cherenkov detector, business.industry, Detector, 01 natural sciences, 030218 nuclear medicine & medical imaging, law.invention, 03 medical and health sciences, 0302 clinical medicine, Software, Data acquisition, law, Control system, 0103 physical sciences, Scalability, High Energy Physics::Experiment, business, Instrumentation, Computer hardware, Graphical user interface

Abstract

A slow control system (SCS) for the Aerogel Ring Imaging Cherenkov (ARICH) counter in the Belle II experiment was newly developed and coded in the development frameworks of the Belle II DAQ software. The ARICH is based on 420 Hybrid Avalanche Photo-Detectors (HAPDs). Each HAPD has 144 pixels to be readout and requires 6 power supply (PS) channels, therefore a total number of 2520 PS channels and 60,480 pixels have to be configured and controlled. Graphical User Interfaces (GUIs) with detector oriented view and device oriented view, were also implemented to ease the detector operation. The ARICH SCS is in operation for detector construction and cosmic rays tests. The paper describes the detailed features of the SCS and preliminary results of operation of a reduced set of hardware which confirm the scalability to the full detector.

Published

2017

3. Test of the HAPD light sensor for the Belle II Aerogel RICH

Author

H. Kawai, K. Hayata, H. Kakuno, K. Ogawa, T. Kumita, Makoto Tabata, Ichiro Adachi, S. Iori, S. Nishida, Samo Korpar, Rok Dolenec, Y. Yusa, R. Kataura, P. Krizan, M. Yonenaga, H. Kindo, T. Sumiyoshi, M. Mrvar, S. Iwata, Luka Santelj, T. Kobayashi, and R. Pestotnik

Subjects

Physics, Nuclear and High Energy Physics, Spectrometer, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, business.industry, Cherenkov detector, Vacuum tube, Photodetector, Avalanche photodiode, 01 natural sciences, law.invention, Electron avalanche, Optics, law, 0103 physical sciences, 010306 general physics, business, Instrumentation, Cherenkov radiation, Dark current

Abstract

The Aerogel Ring-Imaging Cherenkov detector (ARICH) is being installed in the endcap region of Belle II spectrometer to identify particles from B meson decays by detecting the Cherenkov ring image from aerogel radiators. To detect single photons, high-sensitive photon detector which has wide effective area (∼70 mm × 70 mm), a Hybrid Avalanche Photo Detector (HAPD), has been developed in a collaboration with Hamamatsu K.K. The HAPD consists of hybrid structure of a vacuum tube and an avalanche photodiode (APD). It can be operated in 1.5 T magnetic field of the spectrometer and withstands the radiation levels expected in the Belle II experiment. There are two steps of electric pulse amplification: acceleration of photo-electron in electric field in the vacuum tube part and electron avalanche in the APD part resulting in total gain of order 105. For the ARICH, we use 420 HAPDs in total. Before installing them, we performed quality assessment studies such as measurements of dark current, noise level, signal-to-noise ratio and two-dimensional scan with laser illumination. We also measured quantum efficiency of the photocathode. During the HAPD performance tests in the magnetic field, we observed very large signal pulses which cause long dead time of the readout electronics in some of the HAPDs. We have carried out a number of studies to understand this phenomenon, and have found a way to mitigate it and suppress the degradation of the ARICH performance. In this report, we will show a summary of the HAPD performance and quality assessment measurements including validation in the magnetic field for all of the HAPDs manufactured for the ARICH in the Belle II.

Published

2017

4. Recent developments in software for the Belle II aerogel RICH

Author

T. Sumiyoshi, Iki Adachi, Samo Korpar, Rok Dolenec, K. Hataya, P. Križan, K. Ogawa, Hidekazu Kakuno, Shuichi Iwata, M. Yonenaga, H. Kawai, T. Kobayashi, M. Mrvar, S. Ogawa, H. Kindo, Luka Santelj, S. Iori, R. Pestotnik, S. Nishida, T. Kumita, Makoto Tabata, R. Kataura, and Y. Yusa

Subjects

Physics, Nuclear and High Energy Physics, Spectrometer, Physics::Instrumentation and Detectors, business.industry, Detector, Cosmic ray, Aerogel, Nuclear physics, Pion, Software, Radiator (engine cooling), High Energy Physics::Experiment, Nuclear Experiment, business, Instrumentation, Cherenkov radiation

Abstract

For the Belle II spectrometer a proximity focusing RICH counter with an aerogel radiator (ARICH) will be employed as a PID system in the forward end-cap region of the spectrometer. The detector will provide about 4 σ separation of pions and kaons up to momenta of 3.5 GeV/ c , at the kinematic limits of the experiment. We present the up-to-date status of the ARICH simulation and reconstruction software, focusing on the recent improvements of the reconstruction algorithms and detector description in the Geant4 simulation. In addition, as a demonstration of detector readout software functionality we show the first cosmic ray Cherenkov rings observed in the ARICH.

Published

2017

5. The aerogel Ring Imaging Cherenkov system at the Belle II spectrometer

Author

S. Ogawa, T. Kobayashi, Hidekazu Kakuno, K. Ogawa, S. Nishida, Luka Santelj, M. Yonenaga, K. Hataya, M. Mrvar, Samo Korpar, H. Kindo, H. Kawai, Shuichi Iwata, R. Pestotnik, Y. Yusa, R. Kataura, Iki Adachi, T. Sumiyoshi, S. Iori, P. Križan, Makoto Tabata, Rok Dolenec, and T. Kumita

Subjects

Physics, Nuclear and High Energy Physics, Photon, Spectrometer, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, business.industry, Cherenkov detector, Detector, Cosmic ray, Solenoid, 01 natural sciences, law.invention, Optics, Data acquisition, law, 0103 physical sciences, High Energy Physics::Experiment, 010306 general physics, business, Instrumentation, Cherenkov radiation

Abstract

In the forward end-cap of the Belle II spectrometer, a proximity focusing Ring Imaging Cherenkov counter with an aerogel radiator will be installed. The detector will occupy a limited space inside solenoid magnet with longitudinal field of 1.5 T. It will consist of a double layer aerogel radiator, an expansion volume and a photon detector. 420 Hamamatsu hybrid avalanche photo sensors with 144 channels each will be used to read out single Cherenkov photons with high efficiency. More than 60,000 analog signals will be digitized and processed in the front end electronics and send to the unified experiment data acquisition system. The detector components have been successfully produced and are now being installed in the spectrometer. Tested before on the bench, they are currently being installed in the mechanical frame. Part of the detector have been commissioned and connected to the acquisition system to register the cosmic ray particles. The first preliminary results are in accordance with previous expectations. We expect an excellent performance of the device which will allow at least a 4 σ separation of pions from kaons in the experiment kinematic region from 0.5 GeV/c to 4 GeV/c.

Published

2017

6. Studies of a hybrid avalanche photo-detector in magnetic field

Author

T. Sumiyoshi, Shuichi Iwata, P. Križan, A. Stanovnik, S. Ogawa, K. Nath, Makoto Tabata, H. Kindo, Samo Korpar, Hidekazu Kakuno, E. Tahirović, Luka Santelj, Iki Adachi, Y. Yusa, S. Nishida, R. Pestotnik, S. Iori, H. Kawai, A. Seljak, M. Mrvar, R. Kataura, and K. Hataya

Subjects

Physics, Nuclear and High Energy Physics, Photon, Spectrometer, Physics::Instrumentation and Detectors, 010308 nuclear & particles physics, business.industry, Photodetector, Dead time, Radiation, 01 natural sciences, Signal, 010305 fluids & plasmas, Magnetic field, Optics, 0103 physical sciences, Photonics, business, Instrumentation

Abstract

For the Belle II spectrometer a proximity focusing RICH counter with an aerogel radiator (ARICH) will be employed as a PID system in the forward endcap region of the spectrometer. The main challenge was the development of a reliable multichannel sensor for single photons that operates in the high magnetic field of the spectrometer (1.5 T) and withstands the radiation levels expected at the experiment. A 144-channel Hybrid Avalanche Photo-Detector (HAPD) was developed with Hamamatsu Photonics K.K. and the mass production of ∼480 HAPDs was completed recently. While our first tests of HAPD performance in the magnetic field (before mass production) showed no issues, we lately observed a presence of very large signal pulses (∼5000× single photon signal), generated internally within about 20% of HAPDs, while operating in the magnetic field. The rate of these pulses varies from sample to sample. These pulses impact the HAPD performance in two ways: they introduce periods of dead time and, in some cases, damage to the front-end electronics was observed. Here we present conditions under which such large pulses are generated, their properties and impact on HAPD performance, and discuss possible mechanism of their origin.

Published

2017

7. Behaviour of Belle II ARICH Hybrid Avalanche Photo-Detector in magnetic field

Author

T. Sumiyoshi, T. Kobayashi, Luka Santelj, Y. Yusa, Rok Dolenec, S. Ogawa, K. Ogawa, R. Pestotnik, Iki Adachi, P. Kriz^an, T. Konno, S. Iori, M. Yonenaga, K. Hataya, S. Korpar, H. Kawai, M. Mrvar, Makoto Tabata, H. Kindo, Hidekazu Kakuno, Shuichi Iwata, R. Kataura, T. Kumita, and S. Nishida

Subjects

Physics, Nuclear and High Energy Physics, APDS, 010308 nuclear & particles physics, business.industry, Cherenkov detector, Detector, Electrical engineering, Photodetector, Biasing, Dead time, 01 natural sciences, Signal, law.invention, Nuclear physics, law, 0103 physical sciences, 010306 general physics, business, Instrumentation, Voltage

Abstract

The proximity-focusing Aerogel Ring-Imaging Cherenkov detector (ARICH) has been designed to separate kaons from pions in the forward end-cap of the Belle II spectrometer. The detector will be placed in 1.5 T magnetic field and must have immunity to it. In ARICH R&D, we solve the problem with new equipment called Hybrid Avalanche Photo-Detector (HAPD) which developed by Hamamatsu Photonics. Recently the production of about 500 HAPDs was completed. We test HAPDs in magnetic field in KEK. We found some HAPDs have significant amount of dead time, which reaches up to 30% in the worst case. The dead time is caused by very large (more than 10,000 times larger than a single photon signal) and frequent (∼5 Hz) signals, which make electronics paralysed. The huge signals are observed in about 30% of HAPDs. To identify the origin and understand the mechanism, we perform some extra test of HAPDs. We find a strange dependence of the huge signals to the APD bias voltage. If we reduce the bias voltage applied to one of the 4 APDs by 10 V, the frequency of the huge signals is much reduced. On the other hand, if we reduce the voltage of all the 4 HAPDs, huge signals do not decrease, or even increase in some case. We also find the huge signals seems to be related to the vacuum inside HAPD. We present about the observation of the huge signals of HAPDs in the magnetic field, and our strategy to manage it.

Published

2017

8. Implementation of optically simulated luminescent dosimeter for quality control of gamma ray dose of an accelerator-based neutron source.

Author

Hu N, Nakamura T, Kataura R, Suga K, Mukawa T, Akita K, Sasaki A, Nojiri M, Matsubayashi N, Takata T, Tanaka H, Nihei K, and Ono K

Subjects

Humans, Radiotherapy Planning, Computer-Assisted methods, Neoplasms radiotherapy, Radiation Dosimeters standards, Quality Assurance, Health Care standards, Radiometry instrumentation, Radiometry methods, Gamma Rays, Boron Neutron Capture Therapy instrumentation, Boron Neutron Capture Therapy methods, Particle Accelerators instrumentation, Neutrons, Phantoms, Imaging, Radiotherapy Dosage, Quality Control, Monte Carlo Method

Abstract

Background: Neutron beams utilized for performing BNCT are composed of a mixture of neutrons and gamma rays. Although much of the dose delivered to the cancer cells comes from the high LET particles produced by the boron neutron capture reaction, the dose delivered to the healthy tissues from unwanted gamma rays cannot be ignored. With the increase in the number of accelerators for BNCT, a detector system that is capable of measuring gamma ray dose in a mixed neutron/gamma irradiation field is crucial. Currently, BeO TLDs encased in quartz glass are used to measure gamma ray dose in a BNCT irradiation field. However, this type of TLD is no longer commercially available. A replacement dosimetry system is required to perform the recommended ongoing quality assurance of gamma ray measurement for a clinical BNCT system., Purpose: The purpose of this study is to evaluate the characteristics of a BeO OSLD detector system under a mixed neutron and gamma ray irradiation field and to assess the suitability of the system for routine quality assurance measurements of an accelerator-based BNCT facility., Methods: The myOSLD system by RadPro International GmbH was evaluated using the accelerator-based neutron source designed for clinical BNCT (NeuCure BNCT system). The readout constancy, linearity, dose rate effect, and fading effect of the OSLD were evaluated. Free-in-air and water phantom measurements were performed and compared with the TLD results and Monte Carlo simulation results. The PHITS Monte Carlo code was used for this study., Results: The readout constancy was found to be stable over a month-long period and similar to the TLD results. The OSLD readout signal was found to be linear, with a high coefficient of determination (R 2  ≥ 0.999) up to a proton charge of 3.6 C. There was no significant signal fading or dose rate dependency. The central axis depth dose and off-axis dose profile measurements agreed with both the TLD and Monte Carlo simulation results, within one standard deviation., Conclusion: The myOSLD system was characterized using an accelerator system designed for clinical BNCT. The experimental measurements confirmed the OSLD achieved similar, if not superior to, the currently utilized dosimetry system for routine QA of an accelerator-based BNCT system. The OSLD system would be a suitable replacement for the current TLD system for performing routine QA of gamma ray dose measurement in a BNCT irradiation field., (© 2024 The Author(s). Journal of Applied Clinical Medical Physics published by Wiley Periodicals LLC on behalf of American Association of Physicists in Medicine.)

Published

2024