Zeynep Altinbas
Brookhaven National Laboratory
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Featured researches published by Zeynep Altinbas.
arXiv: Accelerator Physics | 2013
W. Fischer; Zeynep Altinbas; M. Anerella; M. Blaskiewicz; D. Bruno; M. Costanzo; W.C.Dawson; D. Gassner; X. Gu; R. Gupta; K. Hamdi; J. Hock; L.T. Hoff; R. Hulsart; A. Jain; R. Lambiase; Y. Luo; M. Mapes; A. Marone; R. Michnoff; Toby Miller; M. Minty; C. Montag; J. Muratore; S. Nemesure; D. Phillips; A. Pikin; S.R.Plate; P. Rosas; L. Snydstrup
In polarized proton operation, the performance of the Relativistic Heavy Ion Collider (RHIC) is limited by the head-on beam-beam effect. To overcome this limitation, two electron lenses are under commissioning. We give an overview of head-on beam-beam compensation in general and in the specific design for RHIC, which is based on electron lenses. The status of installation and commissioning are presented along with plans for the future.
7th Int. Particle Accelerator Conf. (IPAC'16), Busan, Korea, May 8-13, 2016 | 2016
I.V. Pinayev; Zeynep Altinbas; Sergey Belomestnykh; Ilan Ben-Zvi; Kevin M. Brown; Jean Clifford Brutus; Anthony Curcio; Anthony Di Lieto; Charles Folz; D. Gassner; M. Harvey; Thomas Hayes; R. Hulsart; James Jamilkowski; Yichao Jing; D. Kayran; Robert Kellermann; Robert Lambiase; Vladimir N. Litvinenko; G. Mahler; Michael Mapes; W. Meng; K. Mernick; R. Michnoff; Toby Miller; M. Minty; Geetha Narayan; Paul Orfin; David J. Phillips; T. Rao
High-gradient CW photo-injectors operating at high accelerating gradients promise to revolutionize many sciences and applications. They can establish the basis for super-bright monochromatic X-ray and gamma-ray sources, high luminosity hadron colliders, nuclearwaste transmutation or a new generation of microchip production. In this paper we report on our operation of a superconducting RF electron gun with a record-high accelerating gradient at the CsK2Sb photocathode (i.e. ~ 20 MV/m) generating a record-high bunch charge (i.e., 2 nC). We briefly describe the system and then detail our experimental results. INTRODUCTION The coherent electron cooling experiment (CeC PoP) [1, 2] is expected to demonstrate cooling of a single hadron bunch in RHIC. A superconducting RF gun operating at 112 MHz frequencies generates the electron beam. 500MHz normal conducting cavities provide energy chirp for ballistic compression of the beam. 704-MHz superconducting cavity will accelerate beam to the final energy. The electron beam merges with the hadron beam and after cooling process is steered to a dump. The FEL-like structure enhances the electron-hadron interaction. The electron beam parameters are shown in the Table 1. Table 1: Parameters of the Electron Beam
conference of the industrial electronics society | 2014
Robert Lambiase; Zeynep Altinbas
To increase the production of medical isotopes, an upgrade to the Brookhaven Linac Isotope Producer (BLIP) facility is now being designed and constructed. Currently, the ion beam strikes the isotope producing target in a single spot. With this upgrade, the ion beam will be directed to hit the target in circular patterns, distributing the heat of collision over a bigger area on the target. The power system to create the circular patterns requires orthogonal dipole magnets with sinusoidal currents which are ninety degrees apart from each other. This paper describes the design concept for powering the magnets and the control system that produces the correct waveforms despite component variations.
3rd International Particle Accelerator Conference 2012, IPAC 2012 | 2012
W. Fischer; Zeynep Altinbas; M. Anerella; E. Beebe; M. Blaskiewicz; D. Bruno; W.C.Dawson; D. Gassner; X. Gu; R. Gupta; K. Hamdi; J. Hock; L. Hoff; A. Jain; R. Lambiase; Y. Luo; M. Mapes; A. Marone; Toby Miller; M. Minty; C. Montag; M. Okamura; A. Pikin; S.R.Plate; D. Raparia; Y. Tan; C. Theisen; P. Thieberger; J. Tuozzolo; P. Wanderer
Archive | 2014
D. Kayran; Sergey Belomestnykh; R. Than; R. Gupta; Vadim Ptitsyn; T. Rao; A. Zaltsman; Thomas Seda; David Phillips; Vladimir N. Litvinenko; Suresh Deonarine; Chung Ho; Jin Dai; Lee Hammons; Nikolaos Laloudakis; Dana Beavis; Prerana Kankiya; G. Mahler; Zeynep Altinbas; G. McIntyre; K. Smith; Thomas Tallerico; Robert Todd; Wencan Xu; Leonard Masi; D. Gassner; Toby Miller; H. Hahn; Ilan Ben-Zvi; Daniel Weiss
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 2015
X. Gu; Zeynep Altinbas; M. Costanzo; W. Fischer; D. Gassner; J. Hock; Y. Luo; Toby Miller; Y. Tan; P. Thieberger; C. Montag; A. Pikin
5th Int. Particle Accelerator Conf. (IPAC'14), Dresden, Germany, June 15-20, 2014 | 2014
W. Fischer; Zeynep Altinbas; Donald Bruno; Michael Costanzo; Xiaofeng Gu; Jon Hock; A. Jain; Yun Luo; Chaofeng Mi; R. Michnoff; Toby Miller; Alexander Pikin; Theodoro Samms; Yugang Tan; R. Than; P. Thieberger; Simon White
arXiv: Accelerator Physics | 2015
Igor Pinayev; Vladimir N. Litvinenko; J. Tuozzolo; Jean Clifford Brutus; Sergey Belomestnykh; Chase H. Boulware; Charles Folz; D. Gassner; T.L. Grimm; Y. Hao; James Jamilkowski; Yichao Jing; D. Kayran; G. Mahler; Michael Mapes; Toby Miller; Geetha Narayan; B. Sheehy; T. Rao; J. Skaritka; K. Smith; Louis Snydstrup; Yatming Than; Erdong Wang; G. Wang; Binping Xiao; Tianmu Xin; Alexander Zaltsman; Zeynep Altinbas; I. Ben-Zvi
4th International Particle Accelerator Conference, IPAC 2013 | 2013
W. Fischer; Zeynep Altinbas; M. Anerella; D. Bruno; C.D. Dawson; A.K. Drees; D. Gassner; X. Gu; R. Gupta; P. Joshi; J. Hock; L. Hoff; A. Jain; P. Kovach; R. Lambiase; Y. Luo; M. Mapes; A. Marone; A. Marusic; R. Michnoff; Toby Miller; M. Minty; S. Montag; S. Nemesure; S.R.Plate; A. Pikin; L. Snydstrup; Y. Tan; S. Tepikian; R. Than
Archive | 2017
P. Thieberger; A. Pikin; Karim Hamdi; W. Fischer; Toby Miller; Yun Luo; Charles Carlson; Michael Costanzo; Simon White; Xiaofeng Gu; Chellis Chasman; Al Marusic; C. Montag; Christopher Degen; Jon Hock; Kirsten Drees; M. Minty; D. Gassner; Zeynep Altinbas
