Simulations and experiments with space-charge-dominated beams

Kishek, R. A.; Bernal, S.; Bohn, C.L.; Grote, D.P.; Haber, I.; Li, H.; O’Shea, P.G.; Reiser, M.; Walter, M.

doi:10.1063/1.1558291

Cited by 39 publications

(28 citation statements)

References 16 publications

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“…PIC is used to model the injection and acceleration of charge bunches especially when space charge complicates transport and causes emittance growth [19,[44][45][46][47][48]. Indeed, the needs of PIC codes suggest using the PCM approach to develop the "cathode" boundary of the PIC simulation.…”

Section: Gated Structuresmentioning

confidence: 99%

Space charge effects in field emission: One dimensional theory

Rokhlenko

Jensen

Lebowitz

2010

Journal of Applied Physics

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The current associated with field emission is greatly dependent on the electric field at the emitting electrode. This field is a combination of the electric field in vacuum and the space charge created by the current. The latter becomes more important as the current density increases. Here, a study is performed using a modified classical 1D ChildLangmuir description that allows for exact solutions in order to characterize the contributions due to space charge. Methods to connect the 1D approach to an array of periodic 3D structures are considered.

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Section: Gated Structuresmentioning

confidence: 99%

Space charge effects in field emission: One dimensional theory

Rokhlenko

Jensen

Lebowitz

2010

Journal of Applied Physics

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“…COSY INFINITY has also been proposed to expand its code to deal with space charge force [10,11]. A few systematic emittance evolution experiments were done in LINACs [12], and fewer in circular accelerators [4,13]. Systematic measurements and analysis of the emittance evolution with different injection turns at the Fermilab Booster, see e.g., Fig.…”

Section: Introductionmentioning

confidence: 99%

Simulations of beam envelope dynamics in circular accelerators

Chao

Lee

2015

Phys. Rev. ST Accel. Beams

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The envelope instability of high intensity beams in circular accelerators is studied via multiparticle simulations. The space charge kicks are derived from a Gaussian potential model for an efficient tracking. The evolution of the envelope phase space coordinates are derived from the bunch distribution. We found that the envelope stop band played an important role in emittance growth. Correction schemes of the envelope stop bands are studied. Because the space charge force pushes the envelope tunes downward, harmonics less than twice the betatron tunes are also important on emittance growth. Our code is efficient and fast, it can be used to study the effect of space charge force on high power accelerators.

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“…Such a distribution has been experimentally observed in UMER [18]. In order to model such a beam profile, we rotate a Gaussian distribution with width th and offset from the origin around a circle of radius [18]. The parameters th and are obtained empirically such that rms size and emittance of the hollow distribution are the same as the semi-Gaussian distribution in the previous section.…”

Section: A Space Charge Beams and Initial Distributionmentioning

confidence: 99%

“…Therefore, instead of using a S-G we model our tomography process for beams starting with a hollow velocity distribution. Such a distribution has been experimentally observed in UMER [18]. In order to model such a beam profile, we rotate a Gaussian distribution with width th and offset from the origin around a circle of radius [18].…”

Section: A Space Charge Beams and Initial Distributionmentioning

confidence: 99%

“…We simulated the above experimental setup with the particle-in-cell code WARP [16], developed at the Lawrence Livermore National Laboratory. The advantage of WARP is that it self-consistently includes space charge effects and has been successfully benchmarked against UMER experimental data [18]. For each quadrupole current setting, we run a WARP simulation, collect a snapshot of the beam density in configuration space at the phosphor screen location, and then process it to look like a phosphor screen image.…”

Section: Kmentioning

confidence: 99%

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Tomography as a diagnostic tool for phase space mapping of intense particle beams

Stratakis

Kishek

et al. 2006

Phys. Rev. ST Accel. Beams

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A technique is described for the tomographic mapping of transverse phase space in beams with space charge. Most prior studies where performed at high energy where space charge was negligible and therefore not considered in the analysis. The tomographic reconstruction process is compared with results of simulations using the particle-in-cell code WARP. The new tomographic technique is tested for beams with different intensities (both emittance and space-charge dominated), and with different initial distributions. Effects of various errors in the data collection process on the reconstructed phase space are discussed. It is shown that the crucial factor is not necessarily the number of projections but the range of angles over which the projections are taken. This study also includes a number of experimental results on tomographic phase space mapping performed on the University of Maryland Electron Ring.

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Simulations and experiments with space-charge-dominated beams

Cited by 39 publications

References 16 publications

Space charge effects in field emission: One dimensional theory

Space charge effects in field emission: One dimensional theory

Simulations of beam envelope dynamics in circular accelerators

Tomography as a diagnostic tool for phase space mapping of intense particle beams

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