A. Petersen
Stanford University
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Featured researches published by A. Petersen.
Filtration & Separation | 2004
A. J. Edwards; M. Bruinsma; P. R. Burchat; H. Kagan; R. Kass; D. Kirkby; A. Petersen; T. Pulliam
The BaBar experiment has been using two polycrystalline chemical-vapor-deposition (pCVD) diamonds for radiation monitoring for nearly two years. In July 2005, an additional twelve diamond based radiation sensors will be installed inside the BaBar detector. These diamonds will take over the function of twelve silicon PIN-diodes that are currently used in the radiation protection and monitoring system. We describe our experience with using pCVD diamond radiation sensors in a high energy physics experiment. We also detail some of our findings from our research and development of pCVD diamond based radiation sensors.
Physical Review Letters | 1989
R. A. Ong; J. A. Jaros; G. S. Abrams; D. Amidei; A. Baden; T. Barklow; A. M. Boyarski; J. Boyer; P. R. Burchat; D. L. Burke; F. Butler; J. Dorfan; G.J. Feldman; G. Gidal; L. Gladney; M. S. Gold; G. Goldhaber; L. Golding; John S. Haggerty; G. Hanson; K. Hayes; D. Herrup; R. J. Hollebeek; W. R. Innes; I. Juricic; J. Kadyk; D. Karlen; S.R. Klein; A. J. Lankford; R. R. Larsen
We report a new measurement of the average lifetime of hadrons containing bottom quarks. The B hadron decays are tagged by identifying leptons at high transverse momentum. From a fit to the lepton impact parameter distribution, the average B hadron lifetime is found to be (0.98 f 0.12 f 0.13) x lo-l2 sec. The lifetime of hadrons containing bottom quarks is a measure of the strength of the weak transitions between the bottom quark and the charm and up quarks. In terms of the 3 x 3 quark mixing matrix proposed by Kobayashi and Maskawaf the B hadron lifetime depends on the magnitude of the matrix elements Vub and &b. Studies of B semileptonic decay’ have shown that Iv&l is small compared to I&l, and therefore the B lifetime essentially measures II&l and limits lvUbl. The data used in this measurement were collected with the Mark II detector at the e+estorage ring PEP (EC, = 29 GeV). We have previously reported a B lifetime measurement3 based on a data sample of 80 pb-l. The present work: based on a data sample of 204 pb-l, includes the previous data and supersedes our earlier analysis. We use the same procedure of measuring the impact parameters of leptons produced in B decay. However, we have improved upon the previous result through direct measurement of the experimental resolution function, a more precise determination of the B production point, and a comprehensive analysis of inclusive lepton production. These improvements combined with the increased statistics make this measurement of the B lifetime the most precise from any experiment to date. The Mark II detector has been described in detail elsewhere.5 A high resolution drift chamber, known as the vertex chamber, is situated inside the main tracking chamber. The two drift chambers are immersed in a solenoidal magnetic field of 2.3 kG. Particle trajectories are measured with high precision in the (2, y) plane perpendicular to th e b earns, and the impact parameter is accurately determined in that plane. Electrons are identified over 64 % of the solid angle with a lead-liquid-argon calorimeter. Muons are identified over 44 % of the solid angle by-a system of hadron absorbers and proportional tubes.
Physical Review Letters | 1988
R. A. Ong; Walter R. Innes; A. Baden; D. Amidei; R. J. Hollebeek; P. C. Rowson; D.R. Wood; J. Boyer; K. Hayes; D. L. Burke; B. Richter; John S. Haggerty; T. Barklow; G. Hanson; T. Schaad; D. Karlen; F. Butler; W. B. Schmidke; G. Goldhaber; V. Luth; R. R. Larsen; P. R. Burchat; G.J. Feldman; J. Yelton; I. Juricic; H. Schellman; A. J. Lankford; S.R. Klein; M. E. Nelson; J. A. Jaros
We report a new measurement of the average lifetime of hadrons containing bottom quarks. The B hadron decays are tagged by identifying leptons at high transverse momentum. From a fit to the lepton impact parameter distribution, the average B hadron lifetime is found to be (0.98 f 0.12 f 0.13) x lo-l2 sec. The lifetime of hadrons containing bottom quarks is a measure of the strength of the weak transitions between the bottom quark and the charm and up quarks. In terms of the 3 x 3 quark mixing matrix proposed by Kobayashi and Maskawaf the B hadron lifetime depends on the magnitude of the matrix elements Vub and &b. Studies of B semileptonic decay’ have shown that Iv&l is small compared to I&l, and therefore the B lifetime essentially measures II&l and limits lvUbl. The data used in this measurement were collected with the Mark II detector at the e+estorage ring PEP (EC, = 29 GeV). We have previously reported a B lifetime measurement3 based on a data sample of 80 pb-l. The present work: based on a data sample of 204 pb-l, includes the previous data and supersedes our earlier analysis. We use the same procedure of measuring the impact parameters of leptons produced in B decay. However, we have improved upon the previous result through direct measurement of the experimental resolution function, a more precise determination of the B production point, and a comprehensive analysis of inclusive lepton production. These improvements combined with the increased statistics make this measurement of the B lifetime the most precise from any experiment to date. The Mark II detector has been described in detail elsewhere.5 A high resolution drift chamber, known as the vertex chamber, is situated inside the main tracking chamber. The two drift chambers are immersed in a solenoidal magnetic field of 2.3 kG. Particle trajectories are measured with high precision in the (2, y) plane perpendicular to th e b earns, and the impact parameter is accurately determined in that plane. Electrons are identified over 64 % of the solid angle with a lead-liquid-argon calorimeter. Muons are identified over 44 % of the solid angle by-a system of hadron absorbers and proportional tubes.
Physical Review Letters | 1988
R. A. Ong; A. J. Weir; G. S. Abrams; D. Amidei; A. Baden; T. Barklow; A. M. Boyarski; J. Boyer; P. R. Burchat; D. L. Burke; F. Butler; J. M. Dorfan; Gary J. Feldman; G. Gidal; L. Gladney; M. S. Gold; G. Goldhaber; L. Golding; John S. Haggerty; G. Hanson; K. Hayes; D. Herrup; R. J. Hollebeek; Walter R. Innes; J. A. Jaros; I. Juricic; J. A. Kadyk; D. Karlen; S. R. Klein; A. J. Lankford
Physical Review Letters | 1987
S.R. Klein; T. Himel; G. S. Abrams; D. Amidei; A. Baden; T. Barklow; A. M. Boyarski; J. Boyer; P. R. Burchat; D. L. Burke; F. Butler; J. Dorfan; G.J. Feldman; G. Gidal; L. Gladney; M. S. Gold; G. Goldhaber; L. Golding; John S. Haggerty; G. Hanson; K. Hayes; D. Herrup; R. J. Hollebeek; W. R. Innes; J. A. Jaros; I. Juricic; J. Kadyk; D. Karlen; A. J. Lankford; B. LeClaire
Physical Review D | 1989
P. R. Burchat; D. L. Burke; A. Petersen
Physical Review D | 1991
C. von Zanthier; W. De Boer; G. Grindhammer; J. Hylen; Harral B; C. Hearty; L. Labarga; John A. J. Matthews; M. W. Schaad; G. S. Abrams; C.E. Adolphsen; C. Akerlof; J. P. Alexander; M Alvarez; A. Baden; J. Ballam; B. Barish; Timothy Barklow; B. A. Barnett; J Bartelt; D. Blockus; G. Bonvicini; A. M. Boyarski; J. Boyer; B. Brabson; A. Breakstone; J. M. Brom; F. Bulos; P. R. Burchat; David L. Burke
Physical Review Letters | 1987
S.R. Klein; Walter R. Innes; A. Baden; D. Amidei; R. J. Hollebeek; P. C. Rowson; D.R. Wood; J. Boyer; K. Hayes; D. L. Burke; B. Richter; John S. Haggerty; T. Barklow; G. Hanson; T. Schaad; D. Karlen; F. Butler; W. B. Schmidke; G. Goldhaber; V. Luth; R. A. Ong; T. Himel; R. R. Larsen; P. R. Burchat; G.J. Feldman; J. Yelton; I. Juricic; H. Schellman; A. J. Lankford; M. E. Nelson
Physical Review D | 1988
P. R. Burchat; D. L. Burke; A. Petersen