| Paper | Title | Page |
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| MOPHA047 | RF System Design for the TOP-IMPLART Accelerator | 897 |
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| In the ENEA-Frascati research center a linear accelerator for proton therapy is under development in the framework of TOP-IMPLART Project carried out by ENEA in collaboration with ISS and IRE-IFO. The machine is based on a 7 MeV injector operating at a frequency of 425 MHz followed by a sequence of 2997.92 MHz accelerating modules. Five 10 MW klystrons will be used to power all high frequency structures up to a beam energy of 150 MeV. The maximum repetition frequency is 100 Hz and the pulse duration is 4 μs. The RF amplitude and phase stability requirements of the accelerating field are within ±2% and ±2 degrees respectively. For therapeutic use the beam energy will be varied between 85 and 150 MeV by switching off the last modules and varying the electric field amplitude in the last module switched on. Fast control of the RF power supplied to the individual structures allows an energy variation on a pulse by pulse basis; furthermore the system must be able to control the RF phase between accelerating structures. This work describes the RF power distribution scheme and the RF phase and amplitude monitoring system implemented into an embedded control system. | ||
| DOI • | reference for this paper ※ https://doi.org/10.18429/JACoW-IPAC2015-MOPHA047 | |
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| TUPWI003 | Proton Beam Applications for Silicon Bulk Micromachining | 2241 |
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| The irradiation of silicon with ion beams is an established technique to modify its properties. Protons are used for micromachining applications, in conjunction with porous silicon. Porous silicon does not form in areas irradiated with a given fluence of protons (>1014 cm-2). Our work concentrated on the applicability of masked irradiation of silicon wafers with 1.8 MeV proton beams delivered by the TOP-IMPLART LINAC. In our experiments 1-10 Ω*cm n,p-type silicon wafers were masked and irradiated with protons at fluences between 1014 and 1015 protons/cm2. Porous silicon did not form in the irradiated areas up to a distance from the surface corresponding to the stopping range (30um). The suppression of porous silicon formation is due to the to the neutralization of dopant impurities by implanted protons that increases the local resistivity. The interest in using RF LINAC for micromachining applications lies in the possibility of deep implantation, that allows the realization of 3D structures for MEMS applications. The use of metal masks with uniform beams, instead of scanned micro- and nano-metric ion probes, increases throughput achievable in industrial processing of wafers. | ||
| DOI • | reference for this paper ※ https://doi.org/10.18429/JACoW-IPAC2015-TUPWI003 | |
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| TUPWI004 | Status of the TOP-IMPLART Proton LINAC | 2245 |
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| In this work we present the latest update on the TOP-IMPLART LINAC. It is a 150 MeV proton linear accelerator for protontherapy application under realization at ENEA-Frascati in the framework of a project developed by ENEA, the Italian National Institute of Health (ISS) and Regina Elena National Cancer Institute-IFO-Rome. The accelerator consists of a 7 MeV injector operating at 425 MHz followed by a LINAC booster working at 2997.92 MHz at a maximum repetition frequency of 100 Hz. The medium energy section up to 35 MeV is a sequence of four SCDTL modules (Side Coupled Drift Tube LINAC) powered by a single 10 MW klystron: the first module bringing beam energy from 7MeV to 11.6MeV with an input power of 1.3 MW in a 4usec pulse has been successfully commissioned with a 10 uA per pulse beam accelerated at the design energy demonstrating the functionality of low energy proton acceleration at high RF frequency. The effects on beam dynamics, caused by the absence of any harmonic relation between the two operating frequencies of the LINAC has been simulated and experimentally verified during the commissioning activity. The second and third module installation and testing is undergoing. | ||
| DOI • | reference for this paper ※ https://doi.org/10.18429/JACoW-IPAC2015-TUPWI004 | |
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| TUPWI005 | Proton Irradiations of Micro-TOM Red Hairy Roots to Mimic Space Conditions | 2249 |
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Funding: Radiation Sources Laboratory UTAPRAD Department ENEA C.R. Frascati Via E. Fermi, 45 00044 Frascati (RM), Italy ENEA The purpose of the BIOxTREME project, launched by ENEA and funded by ASI (Italian Space Agency), is to formulate new biological drugs having a stimulant activity on the immune system finalizing the production for a ready to use resource in Bioregenerative Life Support Systems (BLSSs) for space missions with extended durations, in deep space, and with multiple crews. One of the project tasks is to study the effects of physical insults on plants, simulating cosmic environment on production platforms by static magnetic fields, microgravity and ionizing radiation. In order to examine the biological effects, to test plant radio-resistance and to build dose-response curves we carried out proton irradiations of a tomato cultivar Micro-Tom red hairy roots with the TOP-IMPLART accelerator at the ENEA Frascati Research center. The biological samples were placed in a holder specially made in a movable real-time monitoring chamber calibrated in dose. The fluence-homogeneity measurements over the sample and the calibration of the monitoring system were performed using GafChromic EBT3 films. The paper describes the experimental set-up and reports the preliminary results. |
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| DOI • | reference for this paper ※ https://doi.org/10.18429/JACoW-IPAC2015-TUPWI005 | |
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