Development of X-Ray Collimators to Identify Sources of Radiation in Devices Insulated by Large Vacuum Gaps

Development of X-Ray Collimators to Identify Sources of Radiation in Devices Insulated by Large Vacuum Gaps

The article outlines the development of a diagnostic system designed to pinpoint the origins of X-ray emissions in high-voltage direct current (HVdc) equipment isolated by large vacuum gaps. Electrons extracted from cathodic surfaces through field emission (FE) processes are accelerated to energies...

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Bibliographic Details
Published in:IEEE transactions on plasma science pp. 1 - 7
Main Authors: Pilan, N., Agostini, M., Fincato, M., Fontana, C. L., Gobbo, R., Lotto, L., Marconato, N., Mario, I., Pasqualotto, R., Pesavento, G., Patton, T., Pino, F., Spagnolo, S., Lorenzi, A. De
Format: Journal Article
Language:English
Published: IEEE 16-04-2024
Subjects:
Apertures
Cathodes
Collimators
Electrostatic accelerators
Electrostatics
high voltage
High-voltage techniques
Power supplies
Scintillators
vacuum
X-ray detectors
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Summary:The article outlines the development of a diagnostic system designed to pinpoint the origins of X-ray emissions in high-voltage direct current (HVdc) equipment isolated by large vacuum gaps. Electrons extracted from cathodic surfaces through field emission (FE) processes are accelerated to energies below 1 MeV, generating bremsstrahlung radiation upon impact with anodic surfaces. This radiation constitutes one of the main evidence that high-voltage conditioning is taking place on a long gap isolated system and with voltages above 50-100 kV. The development of MITICA, the prototype for ITER's neutral beam injector (NBI), necessitates diagnostic systems capable of monitoring the progression of high-voltage conditioning in the electrostatic accelerator. Detectors can be placed in atmospheric air to monitor the evolution of the high-voltage conditioning of the electrostatic accelerator through the metallic vacuum vessel. The adoption of an X-ray collimator embedding a cerium-doped lutetium-based scintillation crystal has been proposed to cope with this target. A prototype of a single-pixel collimator (SPC) with a lead shield and variable geometry has been produced and tested at the high-voltage Padova test facility (HVPTF). High-voltage assessments, reaching up to 780 kVdc, were conducted to refine the collimator design. A multipixel variable-geometry system, utilizing the same technology, is recommended for monitoring the vacuum high-voltage conditioning of the MITICA electrostatic accelerator.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2024.3386933