Streak Camera Enhanced Quadrupole Scan Technique

Gierman, S.M.

doi:10.1142/9789812792181_0035

Cited by 3 publications

(1 citation statement)

References 1 publication

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“…The applied rf field at the time of photoemission needs to be sufficiently high to overcome the image charge. Otherwise, the electron bunch will exhibit temporal distortions characteristic of space-charge limited emission [17]. For a given injection phase, bunch charge, and photoemission radius, the following inequality must be satisfied:…”

Section: Beam Dynamics In An Ncrf Injector a Overcoming Image Chmentioning

confidence: 99%

End-point energy measurements of field emission current in a continuous-wave normal-conducting rf injector

Nguyen

Moody

Andrews

et al. 2011

Phys. Rev. ST Accel. Beams

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The LANL/AES normal-conducting radio-frequency injector has been tested at cw cathode gradients up to 10 MV=m. Field-emission electrons from a roughened copper cathode are accelerated to beam energy as high as 2.5 MeV and impinge on a stainless steel target. The energies of the resulting bremsstrahlung photons are measured at varying levels of injector cavity rf power corresponding to different accelerating gradients. At low cavity power, the bremsstrahlung spectra exhibit well-defined endpoint energies at the positions where the number of single-photon events decreases to one (S=N ratio ¼ 1). Increasing the cavity power raises the probability of two-photon events in which two photons simultaneously arrive at the detector and register counts at twice the photon energy. The end-point energies at high cavity power are recorded at positions where the single-photon events transition to two-photon events. The measured end-point energies using this method are in excellent agreement with PARMELA calculations based on the cavity gradients deduced from the cavity rf power measurements.

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Section: Beam Dynamics In An Ncrf Injector a Overcoming Image Chmentioning

confidence: 99%

End-point energy measurements of field emission current in a continuous-wave normal-conducting rf injector

Nguyen

Moody

Andrews

et al. 2011

Phys. Rev. ST Accel. Beams

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Technological challenges to X-ray FELs

Nuhn

2000

Nuclear Instruments and Methods in Physics Research Section A:

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There is strong interest in the development of x-ray free electron lasers (x-ray FELs). The interest is driven by the scientific opportunities provided by intense, coherent x-rays. An x-ray FEL has all the characteristics of a fourthgeneration source: brightness several orders of magnitude greater than presently achieved in third-generation sources, full transverse coherence, and sub-picosecond long pulses.The SLAC and DESY laboratories have presented detailed design studies for X-Ray FEL user-facilities around the 0.1 nm wavelength-regime (LCLS at SLAC, TESLA X-Ray FEL at DESY). Both laboratories are engaged in proof-of-principle experiments at longer wavelengths (TTF FEL Phase I at 71 nm, VISA at 600-800 nm) with results expected in 1999.The technologies needed to achieve the proposed performances are those of bright electron sources, of acceleration systems capable of preserving the brightness of the source, and of undulators capable of meeting the magnetic and mechanical tolerances that are required for operation in the SASE mode.This paper discusses the technological challenges presented by the X-Ray FEL projects.

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Low emittance photoinjectors

Ferrario

2001

Nuclear Instruments and Methods in Physics Research Section A:

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Streak Camera Enhanced Quadrupole Scan Technique

Cited by 3 publications

References 1 publication

End-point energy measurements of field emission current in a continuous-wave normal-conducting rf injector

End-point energy measurements of field emission current in a continuous-wave normal-conducting rf injector

Technological challenges to X-ray FELs

Low emittance photoinjectors

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