Experimental Demonstration of an RF System for the X-Band Linear Collider

Adolphsen, C.; Andrikopoulos, E.; Burke, D. L.; Chan, Jose; Dolgashev, Valery; Jobe, K.; McCormick, D.; Nelson, J.; Ratcliffe, Krista; Ross, M.; Schultz, D.; Smith, T.; Atkinson, D.; Kazakov, S.; Lounine, A.; Okugi, T.

doi:10.2172/827334

Cited by 3 publications

(2 citation statements)

References 8 publications

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High-Power Rf Distribution Systemfor the 8-Pack Project

Nantista¹

2004

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The 8-Pack Project at SLAC is a prototype rf system whose goal is to demonstrate the high-power X-band technology developed in the NLC/GLC (Next/Global Linear Collider) program. In its first phase, it has reliably produced a 400 ns rf pulse of over 500 MW using a solidstate modulator, four 11.424 GHz klystrons and a dualmoded SLED-II pulse compressor [1]. In Phase 2, the output power of our system has been delivered into the bunker of the NLCTA (Next Linear Collider Test Accelerator) and divided between several accelerator structures for beam acceleration. We describe here the design, cold-test measurements, and processing of this power distribution system. Due to the high power levels and the need for efficiency, overmoded waveguide and components are used. For power transport, the TE 01 mode is used in 7.44 cm and 4.064 cm diameter circular waveguide. Only near the structures is standard WR90 rectangular waveguide employed. Components used to manipulate the rf power include transitional tapers, mode converters, overmoded bends, fractional directional couplers, and hybrids.

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High-Power Rf Distribution Systemfor the 8-Pack Project

Nantista¹

2004

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“…A prototype dual-moded SLED II system for the linear collider was built at NLCTA in 2003 as part of the Eight Pack Project [7]. After high-power processing this system for three weeks, 580 MW, 400 ns pulses were achieved, limited only by the available klystron power.…”

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confidence: 99%

Advances in Normal Conducting Accelerator Technology from the X-Band Linear Collider Program

Adolphsen

Proceedings of the 2005 Particle Accelerator Conference

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In the mid-1990's, groups at SLAC and KEK began dedicated development of X-band (11.4 GHz) rf technology for a next generation, TeV-scale linear collider. The choice of a relatively high frequency, four times that of the SLAC 50 GeV Linac, was motivated by the cost benefits of having lower rf energy per pulse (hence fewer rf sources) and reasonable efficiencies at high gradients (hence shorter linacs). To realize such savings, however, requires operation at gradients and peak powers much higher than that hitherto achieved. During the past twelve years, these challenges were met through innovations on several fronts. This paper reviews these achievements, which include developments in the generation and transport of high power rf, and new insights into high gradient limitations.Presented at the 2005 Particle Accelerator Conference, Knoxville, Tennessee, May 16-20, 2005 * Work supported by Department of Energy contract DE-AC02-76SF00515. ADVANCES IN NORMAL CONDUCTING ACCELERATOR TECHNOLOGY FROM THE X-BAND LINEAR COLLIDER PROGRAM*C. Adolphsen Stanford Linear Accelerator Center, Stanford University, Stanford CA 94309 USA AbstractIn the mid-1990's, groups at SLAC and KEK began dedicated development of X-band (11.4 GHz) rf technology for a next generation, TeV-scale linear collider. The choice of a relatively high frequency, four times that of the SLAC 50 GeV Linac, was motivated by the cost benefits of having lower rf energy per pulse (hence fewer rf sources) and reasonable efficiencies at high gradients (hence shorter linacs). To realize such savings, however, requires operation at gradients and peak powers much higher than that hitherto achieved. During the past twelve years, these challenges were met through innovations on several fronts. This paper reviews these achievements, which include developments in the generation and transport of high power rf, and new insights into high gradient limitations.

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Fast X-Band Phase Shifter

Yakovlev¹

2004

AIP Conference Proceedings

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Experimental Demonstration of an RF System for the X-Band Linear Collider

Cited by 3 publications

References 8 publications

High-Power Rf Distribution Systemfor the 8-Pack Project

High-Power Rf Distribution Systemfor the 8-Pack Project

Advances in Normal Conducting Accelerator Technology from the X-Band Linear Collider Program

Fast X-Band Phase Shifter

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