Paper |
Title |
Page |
TUPME011 |
Simulated Beam-beam Limit for Circular Higgs Factories |
1586 |
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- K. Ohmi
KEK, Ibaraki, Japan
- F. Zimmermann
CERN, Geneva, Switzerland
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We report simulation studies of the beam-beam limit for two proposed circular e+e− Higgs factories with circumference of 27 and 80 km, respectively, called LEP3 and TLEP. In particular we investigate the dependence of the steady-state luminosity and transverse beam sizes on the synchrotron tune (or momentum compaction factor) and on the betatron tunes, as well as the consequences of the strong radiation damping and the implications of the large hourglass effect.
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TUPME012 |
Space Charge Simulation based on a Measured Optics in J-PARC MR |
1589 |
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- K. Ohmi, S. Igarashi, Y. Sato, J. Takano
KEK, Ibaraki, Japan
- S. Hatakeyama
JAEA/J-PARC, Tokai-mura, Japan
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Linear optics parameters, beta, alpha, phase, x-y coupling and dispersion are measured by phase space monitor and/or other tools. Nonlinear effects due to the space charge and magnets are dominantly determined by linear optics. For example, the beam distribution is mainly determined by linear optics, and error of beta function at a sextuple magnet is larger than error of magnet strength generally. This means space charge simulation based on the measured optics takes into account of the major part of errors. We discuss how beam loss degrade and which resonances are induced by the errors in the simulations.
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TUPME013 |
Coherent Thomson Scattering using Beam Echo |
1592 |
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- K. Ohmi, S. Kamada
KEK, Ibaraki, Japan
- H. Fares
Kanazawa University, Kanazawa, Japan
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Longitudinal phase space of the beam is modulated by laser interacting in undulators. The beam can have higher frequency component using the beam echo than than the laser as dicussed by G. Stupakov et al. The modulated beam has a potential to emit coherent radiation with the wave length. We evaluate coherent short wave length (~nm) and/or short pulse (attosec) light source using the beam echo in a low energy accelerator ~100MeV.
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TUPME014 |
Coherent Synchrotron Radiation Predicted at the SuperKEKB Damping Ring |
1595 |
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- H. Ikeda, M. Kikuchi, K. Ohmi, K. Oide, D. Zhou
KEK, Ibaraki, Japan
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The damping ring of SuperKEKB is under construction in order to inject low emittance positron beam into the main ring. We calculated the bunch lengthening and the energy spread caused by the longitudinal wake, which is dominated by the CSR wake field. The result was within the tolerance level.
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TUPME016 |
Crosstalk Between Beam-beam Interaction and Lattice Nonlinearities in the SuperKEKB |
1601 |
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- D. Zhou, K. Ohmi, Y. Ohnishi, K. Oide, H. Sugimoto
KEK, Ibaraki, Japan
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Momentum-dependent lattice nonlinearities have been proven to be important for the luminosity performance in the KEKB B-factory. As an upgrade of KEKB, the SuperKEKB adopts nano-beam scheme, in which the colliding beams are squeezed to extremely small sizes at the interaction point. Consequently, the lattice nonlinearities in SuperKEKB become more stronger than in KEKB. Using two codes, SAD and BBWS, we did various simulations to study the crosstalk between beam-beam interaction and lattice nonlinearities. It is found that lattice nonlinearities can cause remarkable luminosity loss in the SuperKEKB.
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TUPME017 |
Validation of the Microwave Instability in the Damping Ring of SuperKEKB using VFP Solver |
1604 |
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- L. Wang
SLAC, Menlo Park, California, USA
- H. Ikeda, K. Ohmi, K. Oide, D. Zhou
KEK, Ibaraki, Japan
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Microwave instability driven by CSR impedance in the damping ring of Super-KEKB is a concern due to its high bunch current. To understand the beam dynamics, we simulate the microwave instability using Vlasov-Fokker-Planck (VFP) solver. The longitudinal wake potential is calculated as a sum of the contributions due to vacuum chamber components distributed around the ring, including geometry wake field and CSR wake. To improve the accuracy of the simulation of microwave instability, the coherent synchrotron radiation impedance is calculated to very high frequency to get more accurate wake field with a short bunch. The CSR wake is much larger than the geometry wake. The threshold is just above the design current and saw-tooth type of instability is found above the threshold.
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