Electron-cloud simulation and theory for high-current heavy-ion beams

Cohen, R. H.; Friedman, A.; Lund, Steven M.; Molvik, A.W.; Lee, E. P.; Azevedo, T.; Vay, J.-L.; Stoltz, Peter; Veitzer, Seth

doi:10.1103/physrevstab.7.124201

Cited by 18 publications

(11 citation statements)

References 8 publications

(9 reference statements)

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“…The electron line charge is obtained dividing the electron current by the average drift velocity Clearing electrode measurements show that, when the suppressor and clearing electrodes are off, electrons produced at the end wall structures drift through each of the quadrupole magnets at a velocity of 0.60 + 0.11 m/µs. This value was obtained by dividing the time that the electrons need to reach the successive clearing electrodes by the effective magnetic field length of the quadrupole (~32 cm) [15] and it is in excellent agreement with the value of 0.66 m/µs [16] predicted by the simulations. …”

Section: Techniquessupporting

confidence: 78%

Absolute measurement of electron cloud density

Covo¹,

Molvik

Cohen

et al. 2007

2007 IEEE Particle Accelerator Conference (PAC)

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Beam interaction with background gas and walls produces ubiquitous clouds of stray electrons that frequently limit the performance of particle accelerator and storage rings. Counterintuitively we obtained the electron cloud accumulation by measuring the expelled ions that are originated from the beam-background gas interaction, rather than by measuring electrons that reach the walls. The kinetic ion energy measured with a retarding field analyzer (RFA) maps the depressed beam space-charge potential and provides the dynamic electron cloud density. Clearing electrode current measurements give the static electron cloud background that complements and corroborates with the RFA measurements, providing an absolute measurement of electron cloud density during a 5 µs duration beam pulse in a drift region of the magnetic transport section of the High-Current Experiment (HCX) at LBNL.

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Section: Techniquessupporting

confidence: 78%

Absolute measurement of electron cloud density

Covo¹,

Molvik

Cohen

et al. 2007

2007 IEEE Particle Accelerator Conference (PAC)

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“…For electrons, an advanced integrator is being developed that allows large time -steps compared to the electron cyclotron frequency. [3] The lattice description allows a range of field descriptions, from uniform, pure multipole components, to axially varying, mixed components, to gridded field data.…”

Section: Introductionmentioning

confidence: 99%

The WARP Code: Modeling High Intensity Ion Beams

Grote¹,

Friedman²,

Vay³

et al. 2005

AIP Conference Proceedings

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Abstract. The Warp co de, d evelo pe d for heavy -ion d riven iner tial fusion energy s t u dies, is u se d to m o d el high inte n sity ion (an d electro n) bea m s. Significant ca pa bility h a s bee n incor por a te d in War p, allowing n early all sectio n s of a n accelerator to be m o dele d, beginning with t he sou rce. Warp ha s a s its core a n explicit, t h ree -di me n sio nal, p a r ticle -in -cell m o del. Alongside t his is a rich se t of tools for d escribing t h e a p plied field s of t h e accelerator lattice, a n d e m be d de d con d uc ting s urfaces (which are ca p t u re d at s u b -grid resolu tio n). Also incor pora te d are m o dels with re d uce d di me nsionality: a n axisy m me t ric m o d el a n d a tra n sverse "slice" m o del. The code take s a dva ntage of m o de r n p rogra m ming tech niq ues, inclu ding o bject orie nta tion, p a r allelis m, a n d scripting (via Pytho n). It is a t t he forefro n t in t h e u se of t he co m p u ta tional tec hnique of a da p tive m e s h refine me n t, which ha s bee n p a r ticularly s uccessf ul in t h e area of diode a n d injector m o deling, bot h stea dy -st ate a n d timed e p e n de n t. In t he p r e se n ta tio n, so me of t he m ajor a s pects of War p will be overviewe d, especially t h o se t h a t co uld be u sef ul in m o d eling ECR so urces. Warp ha s bee n be nc h m a r ke d against bot h t heo ry a n d ex peri me n t. Recen t re sults will be p re se n te d s howing good agree me nt of War p with experi me n tal res ults fro m t he STS500 injector test s ta n d. Additional infor ma tion ca n be fou n d on t he web p age h t t p: / / hif.lbl.gov / t h eo ry /WARP_su m m a ry.ht ml.

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“…Possible causative mechanisms are envelope mismatch, imperfect applied fields, electron clouds [43], and beam-gas interactions. Collective effects of space-charge waves are expected to relax after several plasma oscillations [44].…”

Section: Transport Through Several Plasma (Beam) Oscillationsmentioning

confidence: 99%

Research and development toward heavy ion driven inertial fusion energy

Seidl

Barnard

Faltens

et al. 2013

Phys. Rev. ST Accel. Beams

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We describe near-term heavy ion fusion (HIF) research objectives associated with developing an inertial fusion energy demonstration power plant. The goal of this near-term research is to lay the essential groundwork for an intermediate research experiment (IRE), designed to demonstrate all the key driver beam manipulations at a meaningful scale, and to enable HIF relevant target physics experiments. This is a very large step in size and complexity compared to HIF experiments to date, and if successful, it would justify proceeding to a demonstration fusion power plant. With an emphasis on accelerator research, this paper is focused on the most important near-term research objectives to justify and to reduce the risks associated with the IRE. The chosen time scale for this research is 5-10 years, to answer key questions associated with the HIF accelerator drivers, in turn enabling a key decision on whether to pursue a much more ambitious and focused inertial fusion energy research and development program. This is consistent with the National Academies of Sciences Review of Inertial Fusion Energy Systems Interim Report, which concludes that ''it would be premature at the present time to choose a particular driver approach. . .'' and encouraged the continued development of community consensus on critical issues, and to develop ''options for a community-based roadmap for the development of inertial fusion as a practical energy source.''

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Electron-cloud simulation and theory for high-current heavy-ion beams

Cited by 18 publications

References 8 publications

Absolute measurement of electron cloud density

Absolute measurement of electron cloud density

The WARP Code: Modeling High Intensity Ion Beams

Research and development toward heavy ion driven inertial fusion energy

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