Js Whitaker
Boston University
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Publication
Featured researches published by Js Whitaker.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1994
K. Abe; P. Antilogus; D. Aston; K.G. Baird; Andrew J. Bean; R. Ben-David; T. Bienz; F. Bird; D.O. Caldwell; M. Cavalli-Sforza; J. Coller; P. Coyle; D. Coyne; S. Dasu; S. Dolinsky; A.B. d'Oliveira; J. Duboscq; W. Dunwoodie; G.D. Hallewell; K. Hasegawa; Y Hasegawa; J. Huber; Y. Iwasaki; P. Jacques; R. A. Johnson; M. Kalelkar; H. Kawahara; Y. Kwon; D. W. G. S. Leith; X. Liu
Abstract This paper describes the performance of a large 4π Cherenkov Ring Imaging Detector (CRID) in the SLD experiment at the SLC at SLAC. We compare the most recent SLD results with those obtained during the R&D period, discuss various design features, and highlight some specific lessons derived from three years of operation.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1996
T. P. A. Åkesson; H. Carling; B. Dolgoshein; C. Fabjan; P. Farthouat; Daniel Froidevaux; W. Funk; S. Furletov; I. Gavrilenko; M. Holder; V.G. Ivochkin; S. Jagielski; O. Kondratiev; S. Konovalov; A. Konstantinov; M. Kopitin; P. Lichard; S. Muraviev; A.V. Nadtochi; P. Nevski; P. R. Norton; V. Peshekhonov; V. Polychronakos; M. Potekhin; V. Radeka; Robert Richter; A. Ramaniouk; D. H. Saxon; V.A. Schegelsky; J. T. Shank
Abstract An 864 channel prototype of an integrated straw tracker and transition radiation detector for tracking and electron identification has been tested with and without magnetic field at the CERN SPS. The rejection against hadrons and converted photons has been measured and the dependence of the rejection power on detection parameters has been investigated. Tracking and hadron rejection were also studied in a high multiplicity environment. The results are compared with Monte Carlo simulations. Wherever possible, conclusions are drawn concerning the performance of a full-scale detector at the future Large Hadron Collider.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1991
K. Abe; P. Antilogus; D. Aston; A. Bean; T. Bienz; F. Bird; David O. Caldwell; P. Coyle; D. Coyne; P. Datte; J. Duboscq; W. Dunwoodie; P. Gagnon; Daniel E. Hale; G.D. Hallewell; K. Hasegawa; M. Hilton; J. Huber; P. Jacques; R. A. Johnson; H. Kawahara; Y. Kwon; D. W. G. S. Leith; A. Lu; J. Martinez; L. Mathys; S. McHugh; R. J. Morrison; D. R. Muller; T Nagamine
Abstract The Stanford Large Detector for experimental particle physics detection at the SLAC Linear Collider contains a Cherenkov ring imaging detector (CRID). The barrel CRID mirrors have been successfully produced and installed. The industrial mirror production process, the quality control of the mirrors produced, and the results of the vacuum ultraviolet (VUV) reflectivity and mirror-shape accuracy are described. An average reflectivity of at least 80% for light at 160 nm and 85% for light in the 180–230 nm wavelength range has been achieved in the production of over 400 mirrors of a typical size of 30 by 30 cm. The surface roughness and optical distortion measurements imply that the light loss due to scattering is a few percent of the incident light and the angular error due to shape distortion is less than 1 mrad.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1991
J.T. Shank; Js Whitaker; V. Polychronakos; V. Radeka; D. Stephani; H. Beker; R. Bock; M. Botlo; C. Fabjan; J. Pfennig; M. J. Price; W. Willis; T. P. A. Åkesson; V. Chernyatin; B. Dolgoshein; P. Nevski; A. Konstantinov; M. Potekhin; A. Romanjuk; V. Sosnovtsev; I. Gavrilenko; S. Muraviev; A. Shmeleva
Abstract A tracking transition radiation detector prototype has been constructed and tested. It consists of 192 straw tubes, 4 mm in diameter, embedded in a polyethylene block acting as radiator. Its performance has been studied as an electron identifier as well as a tracking device for minimum-ionizing particles.
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1990
P. Antilogus; D. Aston; T. Bienz; F. Bird; S. Dasu; W. Dunwoodie; F. Fernandez; G.D. Hallewell; H. Kawahara; P. Korff; Y. Kwon; D. W. G. S. Leith; D. R. Muller; T Nagamine; T.J. Pavel; L. Rabinowitz; B. N. Ratcliff; P.E. Rensing; D. Schultz; S. Shapiro; C. Simopoulos; E. Solodov; N. Toge; J. Va'vra; Sh Williams; Js Whitaker; R.J. Wilson; A. Bean; David O. Caldwell; J. Duboscq
To help ensure the stable long-term operation of a Cherenkov Ring Imaging Detector at high efficiency, a comprehensive monitor and control system is being developed. This system will continuously monitor and maintain the correct operating temperatures, and will provide an on-line monitor of the pressures, flows, mixing, and purity of the various fluids. In addition the velocities and trajectories of Cherenkov photoelectrons drifting within the imaging chambers will be measured using a pulsed UV lamp and a fiberoptic light injection system.
nuclear science symposium and medical imaging conference | 1992
K. Abe; P. Antilogus; D. Aston; K.G. Baird; Andrew J. Bean; R. Ben-David; T. Bienz; F. Bird; D.O. Caldwell; M. Cavalli-Sforza; J.A. Coller; P. Coyle; D. G. Coyne; S. Dasu; S. Dolinsky; A.B. d'Oliveira; J. Duboscq; W. Dunwoodie; P. Gagnon; G.D. Hallewell; K. Hasegawa; Y. Hasegawa; J. Huber; Y. Iwasaki; P. Jacques; R. A. Johnson; M. Kalelkar; H. Kawahara; Y. Kwon; D. W. G. S. Leith
The design and operation of the fluid delivery, monitor, and control systems for the SLD barrel Cherenkov Ring Imaging Detector (CRID) are described. The systems deliver drift gas (C/sub 2/H/sub 6/+TMAE), radiator gas (C/sub 5/F/sub 12/+N/sub 2/), and radiator liquid (C/sub 6/F/sub 14/). Measured critical quantities such as electron lifetime in the drift gas and ultraviolet (UV) transparencies of the radiator fluids, together with the operational experience, are reported. >
ieee nuclear science symposium | 1990
P. Antilogus; D. Aston; T. Bienz; F. Bird; S. Dasu; W. Dunwoodie; G.D. Hallewell; H. Kawahara; Y. Kwon; D. W. G. S. Leith; D. Marshall; D. R. Muller; T. Nagamine; G. Oxoby; B. N. Ratcliff; P.E. Rensing; D. Schultz; S. Shapiro; C. Simopoulos; E. Solodov; P. Stiles; F. Suekane; N. Toge; J. Va'vra; Sh Williams; R.J. Wilson; Js Whitaker; Andrew J. Bean; D.O. Caldwell; J. Duboscq
The front-end electronics of the Cerenkov Ring Imaging Detector (CRID) used in the Stanford Large Detector (SLD) spectrometer at the Stanford Linear Accelerator Center (SLAC) Linear Collider is described. The Plessey process provides a straightforward and low-cost path toward system miniaturization. System tests show good noise performance, calibration precision, system linearity, and signal shape uniformity over the full dynamic range. >
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1996
K. Abe; P. Antilogus; D. Aston; K.G. Baird; C. Baltay; A. Bean; R. Ben-David; T. Bienz; F. Bird; David O. Caldwell; M. Cavalli-Sforza; J.A. Coller; P. Coyle; D. Coyne; S. Dasu; M Dima; A.B. d'Oliveira; J. Duboscq; W. Dunwoodie; G.D. Hallewell; K. Hasegawa; Y Hasegawa; J. Huber; Y. Iwasaki; P. Jacques; R. A. Johnson; M. Kalelkar; H. Kawahara; Y. Kwon; D. W. G. S. Leith
Abstract We describe the likelihood ratio method used for particle identification in the SLD CRID, which allows the use of the entire momentum range covered by the liquid and gas radiators, including the threshold regions. Its application to two preliminary physics analyses is also described.
IEEE Transactions on Nuclear Science | 1990
M. Cavalli-Sforza; P. Coyle; D. Coyne; P. Gagnon; Dc Williams; P. Zucchelli; Js Whitaker; R.J. Wilson; A. Bean; D.O. Caldwell; J. Duboscq; J. Huber; A. Lu; L. Mathys; S. McHugh; R. J. Morrison; M. S. Witherell; S. Yellin; R. A. Johnson; J. Martinez; B. Meadows; M. Nussbaum; A.K.S. Santha; A. Shoup; I. Stockdale; P. Jacques; R.J. Plano; P. Stamer; P. Antilogus; D. Aston
The construction of the Cherenkov Ring Imaging Detector (CRID) for the SLD (Stanford Linear Collider Large Detector) experiment at the SLAC (Stanford Linear Accelerator Center) Linear Collider and the testing of its components is reported. Results are included from testing the drift boxes, liquid radiator trays, and mirrors for the barrel CRID. The development of the support systems essential for the operation of the CRID, namely, gas and liquid recirculation systems and monitoring, are discussed. >
Nuclear Instruments & Methods in Physics Research Section A-accelerators Spectrometers Detectors and Associated Equipment | 1996
K. Abe; P. Antilogus; D. Aston; K.G. Baird; C. Baltay; A. Bean; R. Ben-David; T. Bienz; F. Bird; David O. Caldwell; M. Cavalli-Sforza; J.A. Coller; P. Coyle; D. Coyne; S. Dasu; M Dima; A.B. d'Oliveira; J. Duboscq; W. Dunwoodie; G.D. Hallewell; K. Hasegawa; Y Hasegawa; J. Huber; Y. Iwasaki; P. Jacques; R. A. Johnson; M. Kalelkar; H. Kawahara; Y. Kwon; D. W. G. S. Leith
Abstract The operation and performance of the SLD CRID achieved during the recently completed 1994–1995 run of the SLC will be discussed. Stable operation of liquid (C6F14) and gas (85% C5F12 and 15% N2) radiators with good UV transparency has been achieved. Our expectations for the future SLD physics program will also be briefly discussed.
