Timing stability and control at the E163 laser acceleration experiment

The laser acceleration experiments conducted for the El63 project at the NLC Test Accelerator facility at SLAC have stringent requirements on the temporal properties of the electron and laser beams. A system has been implemented to measure the relative phase stability between the RF sent to the gun,...

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Bibliographic Details
Main Authors: McGuinness, C., Colby, E., Ischebeck, R., Noble, R., Sears, C.M.S., Siemann, R.H., Spencer, J., Walz, D., Plettner, T., Byer, R.L.
Format: Conference Proceeding
Language:English
Subjects:
Acceleration
Electron accelerators
Electron beams
Laser stability
Life estimation
Optical control
Optical pulses
Pulse measurements
Radio frequency
Timing
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Summary:The laser acceleration experiments conducted for the El63 project at the NLC Test Accelerator facility at SLAC have stringent requirements on the temporal properties of the electron and laser beams. A system has been implemented to measure the relative phase stability between the RF sent to the gun, the RF sent to the accelerator, and the laser used to generate the electrons. This system shows rms timing stability better than 1 psec. Temporal synchronicity between the 0.5 psec electron bunch, and the 0.5 psec laser pulse is also of great importance. Cherenkov radiation is used to measure the arrival time of the electron bunch with respect to the laser pulse, and the path length of the laser transport is adjusted to optimize temporal overlap. A linear stage mounted onto a voice coil is used to make shot- by-shot fine timing adjustments to the laser path. The final verification of the desired time stability and control is demonstrated by observing the peak of the laser-electron interaction signal over the course of several minutes.
ISSN:1944-4680
2152-9582
DOI:10.1109/PAC.2007.4440077