PAC07 - List of Authors (Cai, Y.)

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Cai, Y.

Paper	Title	Page
MOZAKI03	PEP-II at 1.2·10³⁴/cm²/s Luminosity	37
	J. Seeman, Y. Cai, M. K. Sullivan, U. Wienands SLAC, Menlo Park, California
	Funding: Work supported by US DOE contract DE-AC02-76SF00515. For the PEP-II Operation Staff: PEP-II is an asymmetric e⁺e^- collider operating at the Upsilon 4S and has recently set several performance records. The luminosity has reached 1.2x10³⁴/cm²/s and has delivered an integrated luminosity of 910/pb in one day. PEP-II operates in continuous injection mode for both beams boosting the integrated luminosity. The peak positron current has reached 3.0 A of positrons and 1.9 A of electrons in 1732 bunches. The total integrated luminosity since turn on in 1999 has reached over 410/fb. This paper reviews the present performance issues of PEP-II and also the planned increase of luminosity in the near future to over 2 x 10³⁴/cm²/s.
	Slides
TUPAN034	Super-B Factory using Low Emittance Storage Rings and Large Crossing Angle	1460
	J. Seeman, Y. Cai, M. K. Sullivan, U. Wienands SLAC, Menlo Park, California M. E. Biagini, P. Raimondi INFN/LNF, Frascati (Roma)
	Funding: Work supported by US DOE contract DE-AC02-76SF00515. Submitted for the High Luminosity Study Group for an Asymmetric Super-B-Factory: Parameters are being studied for a high luminosity e⁺e^- collider operating at the Upsilon 4S that would deliver a luminosity of over 10³⁶/cm²/s. This collider would use a novel combination of linear collider and storage ring techniques. In this scheme an electron beam and a positron beam at 4 GeV x 7 GeV are stored in low-emittance damping rings similar to those designed for a Linear Collider (LC). A LC style interaction region is included in the ring to produce sub-millimeter vertical beta functions at the collision point. A large crossing angle (±30 mrad) is used at the collision point to allow beam separation and reduce the hourglass effect. Beam currents of about 3 A x 2 A in 1700 bunches can produce a luminosity of 10³⁶/cm²/s. Design parameters and beam dynamics effects are discussed.
TUPAN049	Low Emittance Lattices and Final Focus Design for the SuperB Project	1499
	Y. Ohnishi KEK, Ibaraki M. E. Biagini, P. Raimondi INFN/LNF, Frascati (Roma) Y. Cai, J. Seeman, M. K. Sullivan, U. Wienands SLAC, Menlo Park, California A. Wolski Liverpool University, Science Faculty, Liverpool
	For the SuperB project* very low emittances (horizontal < 1 nm) and small beta functions at the Interaction Points are required to achieve the design luminosity of 10³⁶/cm²/s. Low emittance lattice have been designed, using the PEP-II magnets, for the two rings of 4 and 7 GeV, which will have the same emittances and damping times. A new Final Focus section has also been designed to get the strong focusing at the Interaction Point, at the same time providing local correction of the high chromaticity and exploiting the large crossing angle and crabbed waist concepts. Lattice features and chromaticity correction schemes will be discussed. Dynamic apertures, with damping wigglers similar to the ILC ones, will also be presented. * P. Raimondi, "New Developments for SuperB Factories", Invited talk, this Conference
TUPAS070	Optimization of Chromatic Optics Near the Half Integer in PEP-II	1814
	G. Yocky, Y. Cai, F.-J. Decker, Y. Nosochkov, U. Wienands SLAC, Menlo Park, California P. Raimondi INFN/LNF, Frascati (Roma)
	Measurements of the W-function in PEP-II during Run 5 revealed that the chromatic beta functions in both the HER and LER were not optimized. Through a process of measurement, offline analysis and modelling, and high-current run implementation the PEP-II collider luminosity performance was increased by at least 10% by reconfiguring the strengths of sextupoles near the IP to take advantage of a minimized W and increased IP bandwidth.
THPAS058	Lowering the Vertical Emittance in the LER Ring of PEP-II	3621
	F.-J. Decker, Y. Cai, Y. Nosochkov, Y. T. Yan, G. Yocky SLAC, Menlo Park, California
	*Funding: Work supported by Department of Energy contract DE-AC03-76SF00515.** The low energy ring (LER) in PEP-II has a design emittance of 0.5 nm-rad in the vertical, compared to nearly 0.1 nm-rad for the HER ring. This was thought to come from the "vertical step" of about 1 m in the interaction straight, where the LER beam after horizontal separation gets bend vertical so it sits on top of the HER in the rest of the ring. Since the program MAD does not easily reveal the location of the major emittance contribution, a program was written to calculate the coupled "curly H" parameter of mode 2 (mainly vertical) along z. Weighting it with the magnet bending revealed that the weak long bends inside the "vertical step" did less than 20% of the emittance growth. More than 80% comes from the ends of the adjacent arcs with strong bends. This is caused by the coupling cancellation of the solenoid starting already there with the skew quadrupoles SK5 and 6. By introducing additional skews in the straight instead of SK5 and 6 the emittance could be reduced by a factor of ten in simulations, but with very strong skews. Reasonable strong magnets might generate a workable compromise, since a factor of two in emittance promises 50% more luminosity in beam-beam simulations.
THPAS070	Validation of PEP-II Resonantly Excited Turn-by-Turn BPM Data	3645
	Y. T. Yan, Y. Cai, W. S. Colocho, F.-J. Decker SLAC, Menlo Park, California
	Funding: Work supported by US DOE un contract No. DE-AC02-76SF00515 For optics measurement and modeling of the PEP-II electron (HER) and position (LER) storage rings, we have been doing well with MIA* which requires analyzing turn-by-turn Beam Position Monitor (BPM) data that are resonantly excited at the horizontal, vertical, and longitudinal tunes respectively. However, in anticipating that certain BPM buttons or even pins in the PEP-II IR region will be missing for the next run starting in January 2007, we have been developing a data validation process, hoping to reduce the effect due to the reduced BPM data accuracy on PEP-II optics measurement and modeling. Besides the routine process for ranking BPM noise level through data correlation among BPMs, allowing BPMs to have linear gains and linear cross couplings, we can also check BPM data symplecticity by comparing the invariant ratios. We may also work out nonlinear BPM data correction if needed. Results on PEP-II measurement will be presented. * Y. T. Yan, et. al. EPAC06 Proceedings, WEPCH062, (2006)
FRPMS080	Simulation of the Beam-Ion Instability in the Electron Damping Ring of the International Linear Collider	4240
	L. Wang, Y. Cai, T. O. Raubenheimer SLAC, Menlo Park, California
	Funding: Work supported by the U. S. Department of Energy under contract DE-AC02-76SF00515 Ion induced beam instability is one critical issue for the electron damping ring of the International Linear Collider (ILC) due to its ultra small emittance of 2pm. Bunch train filling pattern is proposed to mitigate the instability and bunch-by-bunch feedback is applied to suppress it. Multi-bunch train fill pattern is introduced in the electron beam to reduce the number of trapped ions. Our study shows that the ion effects can be significantly mitigated by using multiple gaps. However, the beam can still suffer from the beam-ion instability driven by the accumulated ions that cannot escape from the beam during the gaps. The effects of beam fill pattern, emittance, vacuum and various damping mechanism are studied using self-consistent program, which includes the optics of the ring.