Paper |
Title |
Page |
MOPP086 |
A Novel Fabrication Technique for the Production of RF Photoinjectors
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751 |
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- P. Frigola, R. B. Agustsson, S. Boucher, A. Y. Murokh
RadiaBeam, Marina del Rey
- D. Cormier, T. Mahale
NCSU, Raleigh
- L. Faillace
Rome University La Sapienza, Roma
- J. B. Rosenzweig, G. Travish
UCLA, Los Angeles, California
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Recent developments in Direct Metal Free Form Fabrication (DMFFF) technology may make it possible to design and produce near netshape copper structures for the next generation of very high duty factor, high gradient radio frequency (RF) photoinjectors. RF and thermal-management optimized geometries could be fully realized without the usual constraints and compromises of conventional machining techniques. A photoinjector design incorporating DMFFF and results from an initial material feasibility study will be reported.
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TUPC072 |
Design and Fabrication of an X-band Traveling Wave Deflection Mode Cavity for Longitudinal Characterization of Ultra-short Electron Beam Pulses
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1215 |
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- A. Y. Murokh, R. B. Agustsson, S. Boucher, P. Frigola
RadiaBeam, Marina del Rey
- D. Alesini
INFN/LNF, Frascati (Roma)
- R. J. England, J. B. Rosenzweig, G. Travish
UCLA, Los Angeles, California
- V. Yakimenko
BNL, Upton, Long Island, New York
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An X-band Traveling wave Deflector mode cavity (XTD) has been developed at Radiabeam Technologies to perform longitudinal characterization of the sub-picosecond ultra-relativistic electron beams. The device is optimized for the 100 MeV electron beam parameters at the Accelerator Test Facility (ATF) at Brookhaven National Laboratory, and is scalable to higher energies. An XTD is designed to operate at 11.424 GHz, and features short filling time, femtosecond resolution, and a small footprint. RF design, fabrication procedure, and commissioning plans are presented. An experimental program at ATF to utilize the deflector for compressed beam characterization is discussed, including proposed measurements of the phase space filamentation due to non-linear processes in a chicane compressor.
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TUPC073 |
A Real-time Bunch Length Terahertz Interferometer
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1218 |
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- G. Andonian, G. Travish
UCLA, Los Angeles, California
- S. Boucher, P. Frigola, A. Y. Murokh
RadiaBeam, Marina del Rey
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With the recent development of advanced photoinjectors and next generation light sources, the progression towards high-current, ultra-short beams is very important. The measurement of these short pulses, with sub-picosecond resolution is essential for successful beam operation and optimization. This paper describes the development of a real-time, shot-to-shot bunch length diagnostic utilizing a novel beam auto-correlation technique.
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TUPP150 |
The Radiatron: A High Average Current Betatron for Industrial and Security Applications
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1860 |
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- S. Boucher, R. B. Agustsson, P. Frigola, A. Y. Murokh, M. Ruelas
RadiaBeam, Los Angeles
- F. H. O'Shea, J. B. Rosenzweig, G. Travish
UCLA, Los Angeles, California
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The fixed-field alternating-gradient (FFAG) betatron has emerged as a viable alternative to RF linacs as a source of high-energy radiation for industrial and security applications. For industrial applications, high average currents at modest relativistic electron beam energies, typically in the 5 to 10 MeV range, are desired for medical product sterilization, food irradiation and materials processing. For security applications, high power x-rays in the 3 to 20 MeV range are needed for rapid screening of cargo containers and vehicles. In a FFAG betatron, high-power output is possible due to high duty factor and fast acceleration cycle: electrons are injected and accelerated in a quasi-CW mode while being confined and focused in the fixed-field alternating-gradient lattice. The beam is accelerated via magnetic induction from a betatron core made with modern low-loss magnetic materials. Here we present the design and status of a prototype FFAG betatron, called the RadiaTron, as well as future prospects for these machines.
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WEPP142 |
Simulation of and Progress towards a Micron-scale Laser-powered Dielectric Electron Source
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2827 |
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- G. Travish, J. B. Rosenzweig, J. Xu
UCLA, Los Angeles, California
- S. Boucher
RadiaBeam, Marina del Rey
- R. B. Yoder
Manhattan College, Riverdale, New York
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A dielectric, slab-symmetric structure for generating and accelerating low-energy electrons has been under study for the past two years. The resonant device is driven by a side-coupled laser and is configured to maintain field provide necessary for synchronous acceleration and focusing of nonrelativistic particles. Intended applications of the structure include the production of radiation for medical treatments, imaging, and industrial uses. The details of the structure geometry and its resonant properties have been studied with 2D and 3D electromagnetic codes, the results of which are present here.
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