An experimental and GEANT4 simulation study on design of a broad energy-range magnetic spectrograph for laser plasma accelerator

Mishra, S. R.; Hazra, Dibyendu; Moorti, A.; Chakera, J. A.

doi:10.1088/1748-0221/15/01/p01034

Cited by 3 publications

(1 citation statement)

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“…The influence of aberrations is reduced with a movable collimator at the entrance to the spectrometer, which restricts the beam transverse size to 0.5 mm. The momentum distribution of beam particles is transformed into the spatial distribution with a vertical deflection of the electron beam in the dipole magnet (figure 21) [13]. The fluorescent screens are installed in the direction of the beam deflection.…”

Section: Beam Energy and Spread Measurements: Magnetic Spectrometermentioning

confidence: 99%

Beam diagnostics for linear accelerator of SKIF synchrotron light source

et al. 2022

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As the injector of the new fourth-generation SKIF synchrotron light source at the BINP SB RAS (Novosibirsk, Russia), the linear accelerator will provide a 200 MeV electron beam. A precise measurement of the beam is very important for the control of the linac and even the entire light source. A set of diagnostic instruments for tuning the linac and measuring the beam parameters starting from the electron RF gun to the output of accelerator has been designed. The instrumentation should cover the dynamic diagnostic range of 0.6 to 200 MeV and a beam duration from the initial 100 ps to 3 ps at the output of the accelerator. The set includes eight fluorescent screens to measure beam transverse size, two Cherenkov probes and RF-cavity sensors to record beam duration, a dipole magnetic spectrometer to measure energy and energy spread, a Faraday cup (FC) and fast current transformers (FCTs) to measure beam charge current, and beam position monitors (BPMs) to check the beam position. This paper aims to give an overview of the beam instrumentation and briefly describes the design and parameters of each diagnostic system. The results of numerical and dynamics simulations of some of the instruments are briefed. Possible scenarios of linac tuning are discussed.

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Section: Beam Energy and Spread Measurements: Magnetic Spectrometermentioning

confidence: 99%

Beam diagnostics for linear accelerator of SKIF synchrotron light source

et al. 2022

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High brightness betatron x-ray source driven by chirped laser pulses

Mishra,

Rao,

Moorti

et al. 2024

Physics of Plasmas

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We demonstrate high brightness betatron x-ray generation from a chirped laser pulses driven plasma accelerator. It is shown that positively chirped laser pulse leads to the initiation and enhancement of collective oscillations of electrons inside plasma bubbles, due to associated pulse front tilt (PFT). The PFT causes transverse drift of the bubbles with respect to the laser axis, which results in high brightness x-ray generation. At an optimum chirp, enhanced x-ray emission of >108 photons/pulse/sr in 0.1% BW with a critical energy of ∼18 keV was observed by a factor >2 in comparison to the case of no chirp. The role of collective oscillation in enhancing x-ray emission is also validated in the Geant4 simulations.

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