Development of frequency-tunable FEM-oscillator with Bragg resonator for testing high-gradient accelerating structures

This paper is devoted to progress in the JINR-IAP FEM experiment based on a 1 MeV/200 A/250 ns LINAC. This FEM generates 30 GHz pulses of 150 - 200 ns pulse duration and 20 - 30 MW power with an efficiency on the level of 20 25%. The high efficiency together with high stability of single-mode single...

Full description

Saved in:
Bibliographic Details
Published in2002 3rd International Conference on Microwave and Millimeter Wave Technology, 2002. Proceedings. ICMMT 2002 pp. 1101 - 1104
Main Authors Ginzburg, N.S., Elzhov, A.V., Ivanov, I.N., Kaminsky, A.K., Kosukhin, V.V., Kuzikov, S.V., Peskov, N.Yu, Petelin, M.I., Perelstein, E.A., Sedykh, S.N., Sergeev, A.P., Sergeev, A.S., Syratchev, I., Wilson, I.
Format Conference Proceeding
LanguageEnglish
Published IEEE 2002
Subjects
Corrugated surfaces
Frequency
Heating
Life estimation
Linear particle accelerator
Magnetic fields
Power generation
Pulse generation
Testing
Tuning
Online AccessGet full text

Cover

More Information
Summary:This paper is devoted to progress in the JINR-IAP FEM experiment based on a 1 MeV/200 A/250 ns LINAC. This FEM generates 30 GHz pulses of 150 - 200 ns pulse duration and 20 - 30 MW power with an efficiency on the level of 20 25%. The high efficiency together with high stability of single-mode single-frequency operation is provided by the use of a reversed guide magnetic field and a novel Bragg resonator with a step of phase of corrugation. At the present stage of the experiments precise tuning of the oscillation frequency was performed by mechanical variation of the value of the phase shift in the Bragg resonator. As a result, the FEM was tuned in the frequency range of 6% with a precision of about 0.1%. Both the spectrum width and the dependence of the frequency tuning value on the corrugation phase shift are in good agreement with the results of simulations. The project to use this high power FEM source for studying surface heating effects in 30 GHz accelerating structures is discussed. A special cavity has been designed to enhance magnetic fields at the cavity surface. The cavity will be studied with regard to 200 - 500/spl deg/C surface pulsed heating stress of the cavity as a consequence of 10/sup 6/ RF-pulses, which are planned to be produced at a repetition rate of 1 Hz.
ISBN:9780780374867
078037486X
DOI:10.1109/ICMMT.2002.1187899