| Paper |
Title |
Page |
| MOPLT156 |
High Brightness Electron Guns for Next-Generation Light Sources and Accelerators
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899 |
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- H. Bluem, M.D. Cole, J. Rathke, T. Schultheiss, A.M.M. Todd
AES, Princeton, New Jersey
- I. Ben-Zvi, T. Srinivasan-Rao
BNL, Upton, Long Island, New York
- P. Colestock, D.C. Nguyen, R.L. Wood, L. Young
LANL, Los Alamos, New Mexico
- D. Janssen
FZR, Dresden
- J. Lewellen
ANL, Argonne, Illinois
- G. Neil, H.L. Phillips, J.P. Preble
Jefferson Lab, Newport News, Virginia
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Advanced Energy Systems continues to develop advanced electron gun and injector concepts. Several of these projects have been previously described, but the progress and status of each will be updated. The project closest to completion is an all superconducting RF (SRF) gun, being developed in collaboration with the Brookhaven National Laboratory, that uses the niobium of the cavity wall itself as the photocathode material. This gun has been fabricated and will shortly be tested with beam. The cavity string for a closely-coupled DC gun and SRF cavity injector that is expected to provide beam quality sufficient for proposed ERL light sources and FELs will be assembled at the Jefferson Laboratory later this year. We are also collaboration with Los Alamos on a prototype CW normal-conducting RF gun with similar performance, that will undergo thermal testing in late 2004. Another CW SRF gun project that uses a high quantum efficiency photocathode, similar to the FZ-Rossendorf approach, has just begun. Finally, we will present the RF design and cold test results for a fully axisymmetric, ultra-high-brightness x-band RF gun.
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| TUPKF072 |
Production and Performance of the CEBAF Upgrade Cryomodule Intermediate Prototypes
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1105 |
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- A-M. Valente, E. Daly, J.R. Delayen, M. Drury, R. Hicks, C. Hovater, J. Mammosser, H.L. Phillips, T. Powers, J.P. Preble, C. Reece, R.A. Rimmer, H. Wang
Jefferson Lab, Newport News, Virginia
- C. Thomas-Madec
SOLEIL, Gif-sur-Yvette
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We have installed two new cryomodules, one in the nuclear physics accelerator (CEBAF) and the other in the Free Electron Laser (FEL) of Jefferson Lab. The new cryomodules consist of 7-cell cavities with the original CEBAF cell shape and were designed to deliver gradients of 70 MV/module. Several significant design innovations were demonstrated in these cryomodules. This paper describes the production procedures, the performance characteristics of these cavities in vertical tests, results of tests in the new cryomodule test facility (CMTF) as well as the commissioning in the CEBAF tunnel and FEL. Performances and limitations after installation in the accelerators are discussed in this paper along with improvements proposed for future cryomodules.
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| TUPKF074 |
Niobium Thin Film Cavity Deposition by ECR Plasma
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1108 |
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- A-M. Valente, H.L. Phillips, H. Wang, A. Wu, G. Wu
Jefferson Lab, Newport News, Virginia
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Nb/Cu technology for superconducting cavities has proven to be over the years a viable alternative to bulk niobium. Energetic vacuum deposition is a very unique alternative method to grow niobium thin film on copper. Single crystal growth of niobium on sapphire substrate has been achieved as well as good surface morphology of niobium on small copper samples. The design of a cavity deposition system is in development. This paper presents the exploratory studies of the influence of the deposition energy on the Nb thin film properties. Several possible venues to achieve Nb/Cu cavity deposition with this technique are also discussed along with the design of the cavity deposition setup under development.
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