192 research outputs found
Study of Beam Diagnostics with Trapped Modes in Third Harmonic Superconducting Cavities at FLASH
Off-axis beams passing through an accelerating cavity excite dipole modes
among other higher order modes (HOMs). These modes have linear dependence on
the transverse beam offset from the cavity axis. Therefore they can be used to
monitor the beam position within the cavity. The fifth dipole passband of the
third harmonic superconducting cavities at FLASH has modes trapped within each
cavity and do not propagate through the adjacent beam pipes, while most other
cavity modes do. This could enable the beam position measurement in individual
cavities. This paper investigates the possibility to use the fifth dipole band
for beam alignment in the third harmonic cavity module. Simulations and
measurements both with and without beam-excitations are presented. Various
analysis methods are used and compared. A good correlation of HOM signals to
the beam position is observed.Comment: 2nd International Particle Accelerator Conference (IPAC '11), San
Sebastian, Spain, Sep 4-9, 201
ELECTRON BEAM DIAGNOSTICS FOR FLASH II
Abstract Up to now, the FLASH linac serves one SASE undulator. The radiation produced can be guided to one of 5 beamlines. In order to increase the availability of the machine, a second undulator section, called FLASH II, will be built in the next 2 years to generate SASE light. A HHG laser will alternatively serve to produce seeded radiation in the undulators. The electron beam diagnostics in FLASH II has to enable the precise control of the beam position, size, timing, as well as the overlap of the electron beam with the HHG laser. Losses have to be kept under control, and the beam has to terminate safely in the beam dump. In comparison to FLASH, which was designed to run with rather high charge, the dynamic range of the diagnostics has to be between 0.1 to 1 nC, similar to the European XFEL. This paper gives an overview of the diagnostics for FLASH II
Coaxial Wire Measurements In NLC Accelerating Structures
The coaxial wire method provides an experimental way of measuring wake fields
without the need for a particle beam. A special setup has been designed and is
in the process of being fabricated at SLAC to measure the loss factors and
synchronous frequencies of dipole modes in both traveling and standing wave
structures for the Next Linear Collider (NLC). The method is described and
predictions based on electromagnetic field simulations are discussedComment: Paper presented at the 2002 8th European Particle Accelerator
Conference (EPAC 2002) Paris, France, June 3rd -June 7th, 200
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