Dark current, breakdown, and magnetic field effects in a multicell, 805 MHz cavity

Norem, J.; Wu, V.; Moretti, A.; Popovic, M.; Qian, Z.; Ducas, Léo; Torun, Y.; Solomey, N.

doi:10.1103/physrevstab.6.072001

Cited by 61 publications

(54 citation statements)

References 22 publications

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“…In the present configuration, optimized for rf tests, a ''dummy'' molybdenum plug is installed instead of a real cathode. The better polishing level of a real cathode plug, and if required, a better cleaning technique to remove particulates [38], and/or a conditioning of the gun at higher rf fields [39] could potentially reduce the dark current intensity.…”

Section: Dark Current Characterizationmentioning

confidence: 99%

Advanced photoinjector experiment photogun commissioning results

Sannibale¹,

Filippetto²,

Papadopoulos³

et al. 2012

Phys. Rev. ST Accel. Beams

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The Advanced Photoinjector Experiment (APEX) at the Lawrence Berkeley National Laboratory is dedicated to the development of a high-brightness high-repetition rate (MHz-class) electron injector for x-ray free-electron laser (FEL) and other applications where high repetition rates and high brightness are simultaneously required. The injector is based on a new concept rf gun utilizing a normal-conducting (NC) cavity resonating in the VHF band at 186 MHz, and operating in continuous wave (cw) mode in conjunction with high quantum efficiency photocathodes capable of delivering the required charge at MHz repetition rates with available laser technology. The APEX activities are staged in three phases. In phase 0, the NC cw gun is built and tested to demonstrate the major milestones to validate the gun design and performance. Also, starting in phase 0 and continuing in phase I, different photocathodes are tested at the gun energy and at full repetition rate for validating candidate materials to operate in a high-repetition rate FEL. In phase II, a room-temperature pulsed linac is added for accelerating the beam at several tens of MeV to reduce space charge effects and allow the measurement of the brightness of the beam from the gun when integrated in an injector scheme. The installation of the phase 0 beam line and the commissioning of the VHF gun are completed, phase I components are under fabrication, and initial design and specification of components and layout for phase II are under way. This paper presents the phase 0 commissioning results with emphasis on the experimental milestones that have successfully demonstrated the APEX gun capability of operating at the required performance.

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Section: Dark Current Characterizationmentioning

confidence: 99%

Advanced photoinjector experiment photogun commissioning results

Sannibale¹,

Filippetto²,

Papadopoulos³

et al. 2012

Phys. Rev. ST Accel. Beams

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“…[1][2][3] Dielectric materials can withstand electric fields roughly 2 orders of magnitude larger than metals at optical frequencies, and together with large electric fields from ultra-short laser pulses, they enable a new acceleration scheme of dielectric laser-driven accelerators (DLAs) that support accelerating gradients up to several GV/m. Many candidates for DLAs have been proposed: grating-based structures, [4][5][6][7] photonic crystal structures, [8][9][10] and woodpile structures.…”

Section: Introductionmentioning

confidence: 99%

Beam quality study for a grating-based dielectric laser-driven accelerator

et al. 2017

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Dielectric laser-driven accelerators (DLAs) based on grating structures are considered to be one of the most promising technologies to reduce the size and cost of future particle accelerators. They offer high accelerating gradients of up to several GV/m in combination with mature lithographic techniques for structure fabrication. This paper numerically investigates the beam quality for acceleration of electrons in a realistic dual-grating DLA. In our simulations, we use beam parameters of the future Compact Linear Accelerator for Research and Applications facility to load an electron bunch into an optimized 100-period dual-grating structure where it interacts with a realistic laser pulse. The emittance, energy spread, and loaded accelerating gradient for modulated electrons are then analyzed in detail. Results from simulations show that an accelerating gradient of up to 1.13 ± 0.15 GV/m with an extremely small emittance growth, 3.6%, can be expected.

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“…Energetic ion collisions with solid targets are an important area of research in basic science [1][2][3][4][5][6][7][8], as well as in numerous industrial applications [9][10][11][12][13][14][15][16]. Tech-X Inc. 1 has been developing multi physics finite-element packages, including TXphysics, OOPIC, and, most recently, VORPAL, that are capable of simulating the dynamics and interaction of metal plasma with the surfaces in various rf structures.…”

Section: Introductionmentioning

confidence: 99%