Your search keyword '"Esperante Daniel"' showing total 2 results

1. A rapid method for prediction of the non-resonant ultra-fast multipactor regime in high gradient RF accelerating structures.

Author

González-Iglesias, Daniel, Gimeno, Benito, Esperante, Daniel, Martinez-Reviriego, Pablo, Martín-Luna, Pablo, Pedraza, Laura Karina, Fernández, Juan Carlos, Fuster-Martínez, Nuria, Martínez, Eduardo, Boronat, Marçà, and Grudiev, Alexej

Abstract

The purpose of this work is to present an analytical method that allows to estimate in an approximate and fast way the presence of the non-resonant and ultra-fast multipactor effect in RF accelerating structures in the presence of high gradient electromagnetic fields. This single-surface multipactor regime, which has been little studied in the scientific literature, is characterised by appearing only under conditions of very strong RF electric fields (of the order of tens or hundreds of MV/m), where it is predominant over other types of single- or dual-surface resonance described in classical multipactor theory. This type of multipactor causes a rapid growth of the electron population and poses a serious drawback in the operation of RF accelerator components operating under high gradient conditions. Specifically, in dielectric-assist accelerating structures (DAA) it has been experimentally found that the presence of multipactor limits the maximum operating gradient of these components due to a significant increase in the reflected power due to the discharge, being this phenomenon the main problem to overcome. In a previous work, we found and described in detail by means of numerical simulations the presence of this non-resonant and ultra-fast multipactor regime in a DAA structure design for hadrontherapy. Here we aim to present a simple and fast method to predict the presence of this non-resonant and ultra-fast multipactor regime in RF accelerator structures with cylindrical revolution symmetry around the acceleration axis. This method is especially useful in the design stages of accelerating structures as it provides much faster results than numerical simulations of the multipactor, with quite good accuracy in a wide range of cases as shown in this paper. • The risk of multipactor discharge in RF structures is analyzed using the MUNAMP method. • This MUNAMP method predicts ultrafast non-resonant multipactor. • In DAA devices, MUNAMP compares well with Monte-Carlo simulations in analysed cases. • MUNAMP is faster but less accurate than Monte-Carlo method for multipactor analysis. [ABSTRACT FROM AUTHOR]

Published

2024

2. Non-resonant ultra-fast multipactor regime in dielectric-assist accelerating structures.

Author

González-Iglesias, Daniel, Gimeno, Benito, Esperante, Daniel, Martinez-Reviriego, Pablo, Martín-Luna, Pablo, Fuster-Martínez, Nuria, Blanch, César, Martínez, Eduardo, Menendez, Abraham, Fuster, Juan, and Grudiev, Alexej

Abstract

The objective of this work is the evaluation of the risk of suffering a multipactor discharge in an S-band dielectric-assist accelerating (DAA) structure for a compact low-energy linear particle accelerator dedicated to hadrontherapy treatments. A DAA structure consists of ultra-low loss dielectric cylinders and disks with irises which are periodically arranged in a metallic enclosure, with the advantage of having an extremely high quality factor and very high shunt impedance at room temperature, and it is therefore proposed as a potential alternative to conventional disk-loaded copper structures. However, it has been observed that these structures suffer from multipactor discharges. In fact, multipactor is one of the main problems of these devices, as it limits the maximum accelerating gradient. Because of this, the analysis of multipactor risk in the early design steps of DAA cavities is crucial to ensure the correct performance of the device after fabrication. In this paper, we present a comprehensive and detailed study of multipactor in our DAA design through numerical simulations performed with an in-house developed code based on the Monte–Carlo method. The phenomenology of the multipactor (resonant electron trajectories, electron flight time between impacts, etc.) is described in detail for different values of the accelerating gradient. It has been found that in these structures an ultra-fast non-resonant multipactor appears, which is different from the types of multipactor theoretically studied in the scientific literature. In addition, the effect of several low electron emission coatings on the multipactor threshold is investigated. Furthermore, a novel design based on the modification of the DAA cell geometry for multipactor mitigation is introduced, which shows a significant increase in the accelerating gradient handling capabilities of our prototype. • Multipactor discharge risk in a dielectric-assisted accelerator is analyzed by numerical simulations. • Multipactor phenomenology and electron statistics in the DAA cell are examined. • Analysis of dielectric coatings to reduce the SEY and suppress the multipactor. • Modification of the DAA cell geometry to mitigate the multipactor is investigated [ABSTRACT FROM AUTHOR]

Published

2024