In this paper, we illustrate the RF design and measurements of a C-band prototype structure for an Ultra High Dose Rate medical linac. (1) Background: FLASH Radiotherapy (RT) is a revolutionary new technique for cancer cure. It releases ultra-high radiation dose rates (above 100 Gy/s) in microsecond short pulses. In order to obtain a high dose in a very short time, accelerators with high-intensity currents (the order of 100 mA peak currents) have to be developed. In this contest, Sapienza University, in collaboration with SIT-Sordina IORT Technology spa, is developing a new C-band linac to achieve the FLASH regime. (2) Methods: We performed the RF electromagnetic design of the prototype of the C band linac using CST STUDIO Suite Code and the RF low power RF test at Sapienza University of Rome. The measurements of the field in the cavity have been done with the bead-pull technique. (3) Results: This device is a nine-cell structure operating on the (Formula presented.) mode at 5.712 GHz (C-band). We report and discuss the test measurement results on a full-scale copper prototype, showing good agreement with CST RF simulations. A tuning procedure has been implemented in order to ensure proper operating frequency and to reach a field profile flatness of the order of a few percent. (4) Conclusions: The prototype of a C-band linac for FLASH applications was successfully tested with low RF power at Sapienza University. The fabrication and ad hoc tuning procedures have been optimized and discussed in the paper.

RF design and measurements of a C-Band prototype structure for an Ultra-High Dose-Rate medical linac / Giuliano, L.; Bosco, F.; Carillo, M.; Felici, G.; Ficcadenti, L.; Mostacci, A.; Migliorati, M.; Palumbo, L.; Spataro, B.; Faillace, L.. - In: INSTRUMENTS. - ISSN 2410-390X. - 7:1(2023). [10.3390/instruments7010010]

RF design and measurements of a C-Band prototype structure for an Ultra-High Dose-Rate medical linac

Giuliano L.;Carillo M.;Ficcadenti L.;Mostacci A.;Migliorati M.;Palumbo L.;Spataro B.;Faillace L.
2023

Abstract

In this paper, we illustrate the RF design and measurements of a C-band prototype structure for an Ultra High Dose Rate medical linac. (1) Background: FLASH Radiotherapy (RT) is a revolutionary new technique for cancer cure. It releases ultra-high radiation dose rates (above 100 Gy/s) in microsecond short pulses. In order to obtain a high dose in a very short time, accelerators with high-intensity currents (the order of 100 mA peak currents) have to be developed. In this contest, Sapienza University, in collaboration with SIT-Sordina IORT Technology spa, is developing a new C-band linac to achieve the FLASH regime. (2) Methods: We performed the RF electromagnetic design of the prototype of the C band linac using CST STUDIO Suite Code and the RF low power RF test at Sapienza University of Rome. The measurements of the field in the cavity have been done with the bead-pull technique. (3) Results: This device is a nine-cell structure operating on the (Formula presented.) mode at 5.712 GHz (C-band). We report and discuss the test measurement results on a full-scale copper prototype, showing good agreement with CST RF simulations. A tuning procedure has been implemented in order to ensure proper operating frequency and to reach a field profile flatness of the order of a few percent. (4) Conclusions: The prototype of a C-band linac for FLASH applications was successfully tested with low RF power at Sapienza University. The fabrication and ad hoc tuning procedures have been optimized and discussed in the paper.
2023
C-band; linear accelerator; RF design; RF measurements
01 Pubblicazione su rivista::01a Articolo in rivista
RF design and measurements of a C-Band prototype structure for an Ultra-High Dose-Rate medical linac / Giuliano, L.; Bosco, F.; Carillo, M.; Felici, G.; Ficcadenti, L.; Mostacci, A.; Migliorati, M.; Palumbo, L.; Spataro, B.; Faillace, L.. - In: INSTRUMENTS. - ISSN 2410-390X. - 7:1(2023). [10.3390/instruments7010010]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1683786
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