B
B. N. Ratcliff
Researcher at Stanford University
Publications - 34
Citations - 13781
B. N. Ratcliff is an academic researcher from Stanford University. The author has contributed to research in topics: Cherenkov radiation & Particle detector. The author has an hindex of 14, co-authored 34 publications receiving 11943 citations.
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Journal ArticleDOI
Monitor and control systems for the SLD Cherenkov Ring Imaging Detector
P. Antilogus,D. Aston,T. Bienz,F. Bird,S. Dasu,W. Dunwoodie,F. Fernandez,G. Hallewell,H. Kawahara,P. Korff,Y. Kwon,D. W. G. S. Leith,Dominik Müller,T. Nagamine,T.J. Pavel,L. Rabinowitz,B. N. Ratcliff,P.E. Rensing,D.C. Schultz,S. L. Shapiro,C. Simopoulos,E. P. Solodov,N. Toge,J. Va'vra,S. H. Williams,J. S. Whitaker,Robert Wilson,A. Bean,David O. Caldwell,J. Duboscq,J. Huber,A. Lu,S. McHugh,L. Mathys,R. J. Morrison,Michael S. Witherell,S. Yellin,M. Cavalli-Sforza,P. Coyle,D. G. Coyne,P. Gagnon,David A. Williams,P. Zucchelli,S. Attanagoda,Randall P. Johnson,J. Martinez,B. Meadows,M. Nussbaum,A. L. Shoup,M.D. Sokoloff,I. Stockdale,R. Plano,P. Jacques,P. Stamer,Koya Abe,K. Hasegawa,F. Suekane,H. Yuta +57 more
TL;DR: In this article, a comprehensive monitor and control system for a Cherenkov ring-imaging detector was developed to help ensure the stable long-term operation of a CH detector at high efficiency.
Journal ArticleDOI
Future high energy physics experiments using RICH detectors: the next generation
TL;DR: The physics goals and detector designs of high energy physics experiments now under construction that use RICH technology for particle identification are reviewed in this paper, where the authors also present their own experiments using RICH.
Journal ArticleDOI
The fluid systems for the SLD Cherenkov Ring Imaging Detector
Koji Abe,P. Antilogus,P. Antilogus,D. Aston,K.G. Baird,A. Bean,R. Ben-David,T. Bienz,T. Bienz,F. Bird,David O. Caldwell,M. Cavalli-Sforza,J. A. Coller,P. Coyle,P. Coyle,D. G. Coyne,S. Dasu,S. Dasu,S. Dolinsky,S. Dolinsky,A.B. d'Oliveira,A.B. d'Oliveira,J. Duboscq,W. Dunwoodie,P. Gagnon,G. Hallewell,G. Hallewell,Kazuo Hasegawa,Y. Hasegawa,J. Huber,J. Huber,Y. Iwasaki,P. Jacques,R. A. Johnson,M. Kalelkar,H. Kawahara,Y. Kwon,D. W. G. S. Leith,X. Liu,A. Lu,S. Manly,J. Martinez,L. Mathys,M. McCulloch,S. McHugh,D. McShurley,G. Muller,Dominik Müller,T. Nagamine,M. Nussbaum,T.J. Pavel,H. Peterson,R. Plano,B. N. Ratcliff,R. Reif,P.E. Rensing,A.K.S. Santha,M. Schneider,D.C. Schultz,J.T. Shank,S. L. Shapiro,H. Shaw,C. Simopoulos,J. A. Snyder,Michael Sokoloff,E. P. Solodov,E. P. Solodov,P. Stamer,I. Stockdale,I. Stockdale,F. Suekane,N. Toge,J. D. Turk,J. Va'vra,R. Watt,T. Weber,J. S. Whitaker,David A. Williams,S. H. Williams,Robert Wilson,G. B. Word,S. Yellin,H. Yuta +82 more
TL;DR: In this paper, the design and operation of the fluid delivery, monitor, and control systems for the SLD barrel Cherenkov Ring Imaging Detector (CRID) are described.
Journal ArticleDOI
Operational status and performance of the SLD CRID
K. Abe,P. Antilogus,D. Aston,K.G. Baird,C. Baltay,A. Bean,R. Ben-David,T. Bienz,F. Bird,D. O. Caldwell,M. Cavalli-Sforza,J. A. Coller,P. Coyle,D. G. Coyne,S. Dasu,M. Dima,A.B. d'Oliveira,J. Duboscq,W. Dunwoodie,G. Hallewell,Kazuo Hasegawa,Y. Hasegawa,J. Huber,Y. Iwasaki,P.F. Jacques,R. A. Johnson,M. Kalelkar,H. Kawahara,Yeong-Dae Kwon,D. W. G. S. Leith,X. Liu,A. Lu,S. Manly,J. Martinez,L. Mathys,S. McHugh,Brian Meadows,G. Muller,Dominik Müller,T. Nagamine,S. Narita,M. Nussbaum,T.J. Pavel,R.J. Plano,B. N. Ratcliff,P.E. Rensing,A.K.S. Santha,D.C. Schultz,S. Sen,James Shank,S. L. Shapiro,C. Simopoulos,J Snyder,E. P. Solodov,P. E. Stamer,I. Stockdale,F. Suekane,N. Toge,J. D. Turk,J. Va'vra,J. S. Whitaker,David A. Williams,S. H. Williams,S. Willocq,Robert Wilson,G. B. Word,S. J. Yellin,H. Yuta +67 more
TL;DR: In this paper, the operation and performance of the SLD CRID achieved during the recently completed 1994-1995 run of SLC was discussed and the expectations for the future SLD physics program were briefly discussed.
Journal ArticleDOI
Cherenkov Ring Imaging Detector front-end electronics
P. Antilogus,D. Aston,T. Bienz,F. Bird,S. Dasu,W. Dunwoodie,G. Hallewell,H. Kawahara,Y. Kwon,D. W. G. S. Leith,D. Marshall,Dominik Müller,T. Nagamine,G. Oxoby,B. N. Ratcliff,P.E. Rensing,D.C. Schultz,S. L. Shapiro,C. Simopoulos,E. P. Solodov,P. Stiles,F. Suekane,N. Toge,J. Va'vra,S. H. Williams,Robert Wilson,J. S. Whitaker,A. Bean,David O. Caldwell,J. Duboscq,J. Huber,A. Lu,L. Mathys,S. McHugh,R. J. Morrison,Michael S. Witherell,S. Yellin,P. Coyle,D. G. Coyne,E.N. Spencer,A. d'Oliveria,R. A. Johnson,J. Martinez,M. Nussbaum,A.K.S. Santha,A. L. Shoup,I. Stockdale,P. Jacques,R. Plano,P. Stamer,Kota Abe,K. Hasegawa,H. Yuta +52 more
TL;DR: The Plessey process provides a straightforward and low-cost path toward system miniaturization as discussed by the authors, and the front-end electronics of the Cerenkov ring imaging detector used in the Stanford Large Detector (SLD) spectrometer at the Stanford Linear Accelerator Center (SLAC) Linear Collider is described.