Your search keyword '"S F, Pate"' showing total 357 results

351. Compound versus direct processes in the 12C(14N, d)24Mg∗ reaction

Author

S. Saini, S. F. Pate, P.H. Kutt, R. Zurmühle, and A.H. Wuosmaa

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, medicine.anatomical_structure, Deuterium, medicine, State (functional analysis), Direct transfer, Atomic physics, Nucleus

Abstract

Angular correlations of deuterons and α-particles have been measured for the 12 C ( 14 N , d ) 24 Mg ∗ (α) 20 Ne ( g.s. ) reaction. No evidence is found for the direct transfer of a 12C nucleus populating the 13.45 MeV (6+) state of 24Mg. Angular correlations for this state and several others are relatively featureless. This result is in disagreement with a recently published measurement.

Published

1986

352. Resonance behavior in the24Mg+28Si system

Author

S. Saini, R. R. Betts, S. F. Pate, R. W. Zurmühle, A. H. Wuosmaa, and P. H. Kutt

Subjects

Nuclear reaction, Physics, Elastic scattering, Nuclear and High Energy Physics, Scattering, Q value, Resonance, Isotopes of silicon, Atomic physics, Inelastic scattering, Excitation

Abstract

We have measured excitation functions for elastic and inelastic scattering of the nonsymmetric alpha-particle system of /sup 24/Mg+ /sup 28/Si, in the energy range 90.95 MeV

Published

1987

353. Single and correlated spin alignments for resonances inMg24+Mg24inelastic scattering

Author

P. H. Kutt, A. H. Wuosmaa, S. Saini, R. W. Zurmühle, S. F. Pate, D. C. Hensley, and M. L. Halbert

Subjects

Nuclear reaction, Physics, education.field_of_study, Angular momentum, Scattering, Population, General Physics and Astronomy, Resonance, Inelastic scattering, Atomic physics, Polarization (waves), education, Isotopes of magnesium

Abstract

We have measured the single and correlated magnetic-substate population parameters for the 2/sup +/ and 2/sup +/-2/sup +/ excitations in /sup 24/Mg+ /sup 24/Mg in the region of two strong resonances seen in inelastic scattering. We interpret our data in terms of an isolated resonance decaying through one preferred l value in both the 2/sup +/ and 2/sup +/-2/sup +/ channels. Our data suggest a spin assignment of J/sup ..pi../ = 36/sup +/ for the resonance at E/sub c.m./ = 45.70 MeV, and a value of l = 34 for the grazing angular momentum for both the single and mutual inelastic-scattering channels.

Published

1987

354. Electric quadrupole-quadrupole interaction in two dimensions: Fluctuation effects with zero substrate potential

Author

S. F. Pate and M. A. Klenin

Subjects

Materials science, Condensed matter physics, Quadrupole, Zero (complex analysis), Substrate (chemistry)

Published

1982

355. First results from RHIC-PHENIX

Author

V. S. Pantuev, R. A. Soltz, Y. Nakada, J. Kikuchi, Y. Kwon, M. Grosse Perdekamp, H. Wang, A. Kiyomichi, Junji Tojo, P. Pitukhin, T. A. Carey, Shunji Nishimura, T. L. Thomas, O. Dietzsch, V. Kochetkov, W. W. Kinnison, M. J. Leitch, E. Taniguchi, Dipanwita Dutta, David Olle Rickard Silvermyr, K. S. Sim, M. Sugioka, M. D. Marx, Julia Velkovska, S. Nagamiya, J. S. Haggerty, C. Witzig, Ryugo S. Hayano, S. T. Belyaev, S. Markacs, Y. Riabov, H. Tsuruoka, Alexei Khanzadeev, H. D. Sato, Kenta Shigaki, S-Y Fung, L. Kochenda, T. Matsumoto, M. A. Volkov, D. J. Lim, Sean A. Kelly, M. Rosati, A. S. Nyanin, M. Suzuki, M. Velkovsky, J. Chiba, V. Bumazhnov, P. W. Stankus, M. Pollack, E. Stenlund, E. P. Hartouni, S. Esumi, M. Messer, M. Chiu, A. A. Vinogradov, Henrik Tydesjö, A. Franz, Terry C Awes, G. C. Mishra, Agneta Oskarsson, B. V. Dinesh, A. Kozlov, W. A. Zajc, C. Velissaris, G. R. Young, R. Seto, I. Ravinovich, C. A. Ogilvie, T. K. Hemmick, Y. Berdnikov, Martin Purschke, N. N. Ajitanand, T. Peitzmann, Saskia Mioduszewski, Z. Sun, J. P. Sullivan, J. Simon-Gilio, James Alexander, Jiangyong Jia, Y. Goto, Yasuo Miake, V. Cianciolo, N. Starinsky, Lennart Osterman, C. L. Woody, Senta Greene, Kazuhiro Tanaka, Sergey Fokin, W. C. Chang, F. Plasil, Zhongfan Liu, Roy A. Lacey, Klaus Johannes Reygers, B. R. Schlei, C. P. Singh, S. F. Pate, F. G. Bellaiche, Minghui Liu, B. M. Johnson, Takao Sakaguchi, S. K. Mark, C. Klein-Boesing, Juergen Thomas, A. L. Godoi, S. Bathe, X. Liu, S. Yokkaichi, X. He, S. K. Tuli, Hyun-Chul Kim, Kenichi Imai, A. Hoover, J. Murata, B. K. Nandi, A. D. Frawley, Yves Roland Schutz, G. S. Kyle, C. Pinkenburg, S. S. Adler, M. Ishihara, N. Bruner, E. Vznuzdaev, V. Baublis, D. J. Kim, Hideki Hamagaki, H. A. Gustafsson, S. H. Aronson, S. Butsyk, E. O'Brien, P. Steinberg, Vladimir Samsonov, David D'Enterria, J. M. Heuser, S. K. Gupta, R. P. Pisani, E. M. Takagui, W. Y. Jang, T. Shiina, I. Shein, R. S. Towell, T-A Shibata, G. David, Y. I. Makdisi, T. K. Shea, L. L. Chavez, R. Averbeck, Byung-Sik Hong, Z. Fraenkel, A. A. Tsvetkov, Athanasios Petridis, Nikolay Tyurin, I. Otterlund, A. Bazilevsky, S. S. Ryu, Y. Akiba, A. A. Rose, Alexandre Lebedev, J. H. Thomas, F. Matathias, M. Kann, Kensuke Homma, E. Melnikov, S. Chernichenko, Wei Xie, J. Barrette, German Martinez, A. Deshpande, J. T. Mitchell, S. N. White, L. Paffrath, B. Bassalleck, F. Mühlbacher, Viktor Riabov, Kenneth Francis Read, Zhen Zhang, S. C. Johnson, Y. J. Mao, S. Klinksiek, Charles Maguire, N. Hayashi, A. Drees, M. J. Kweon, H. Hara, J. L. Nagle, H. W. Van Hecke, W. Guryn, Y. Sumi, Josh Moss, M. Tamai, D. M. Lee, L. Ewell, S. Garpman, R. E. Mischke, D. S. Ho, C. Y. Chi, A. Durum, K. N. Barish, Y. G. Kim, M. S. Chung, M. J. Bennett, A. Denisov, E. Kistenev, P. Chung, Mikhail Ippolitov, M. Ono, S. Kametani, S. Sawada, I. G. Sibiriak, D. S. Brown, S. Botelho, S. S. Kapoor, M. J. Tannenbaum, H. Torii, Y. Watanabe, M. Merschmeier, Yasushi Nagasaka, V. Papavassiliou, Atsushi Taketani, D. Bucher, M. L. Brooks, S. Y. Kim, D. E. Fields, T. Ushiroda, A. Masaike, B. V. Jacak, Vladislav Manko, Brian Cole, Y. Tanaka, A K Mohanty, V.A. Onuchin, S. Belikov, G. Bunce, A. G. Hansen, H. Delagrange, A. Soldatov, T. Ferdousi, T. Chujo, John Hill, K. Oyama, J. Chang, Norio Saito, T. C. Sangster, Toru Sugitate, J.R. Mahon, K. El Chenawi, Z. Li, Yoshio Arai, J. Lauret, T. Ichihara, F. K. Wohn, Aya Sakaguchi, T. Kohama, K. Yagi, S. Zhou, T. K. Ghosh, I. D. Ojha, W. Tian, Susumu Sato, R. K. Choudhury, Ju Hwan Kang, M. Muniruzzaman, P. D. Barnes, T. E. Miller, Laurent Bernard Aphecetche, R. Santo, K. Pope, A. Glenn, Hiroyuki Sako, B. Khachaturov, D. Kochetkov, Alexander Milov, D. P. Morrison, V. E. Semenov, T. Christ, I. Tserruya, Yu. Efremenko, V. Singh, D. Koehler, Joakim Nystrand, K. Ebisu, S. P. Stoll, P. Chand, Y. H. Shin, Tai Sakuma, P. L. McGaughey, P. J. Kroon, J. M. Burward-Hoy, A. Ster, K. S. Joo, F. Messer, Paul Nilsson, An.A. Vorobyov, K. Adcox, S. P. Sorensen, J. G. Lajoie, H. En'yo, K. Kurita, M. Sivertz, Hiroaki Ohnishi, L. Nikkinen, H. Buesching, Xingguo Li, Jason Newby, E. J. Desmond, A. P.T. Palounek, and I. E. Yushmanov

Subjects

Physics, Quantum chromodynamics, Particle physics, Large Hadron Collider, Calorimeter (particle physics), Physics::Instrumentation and Detectors, General Physics and Astronomy, Particle identification, Charged particle, Nuclear physics, Quark–gluon plasma, High Energy Physics::Experiment, Nuclear Experiment, Relativistic Heavy Ion Collider, Glauber

Abstract

The PHENIX experiment consists of a large detector system located at the newly commissioned relativistic heavy ion collider (RHIC) at the Brookhaven National Laboratory. The primary goal of the PHENIX experiment is to look for signatures of the QCD prediction of a deconfined high-energy-density phase of nuclear matter quark gluon plasma. PHENIX started data taking for Au+Au collisions at √sNN=130 GeV in June 2000. The signals from the beam-beam counter (BBC) and zero degree calorimeter (ZDC) are used to determine the centrality of the collision. A Glauber model reproduces the ZDC spectrum reasonably well to determine the participants in a collision. Charged particle multiplicity distribution from the first PHENIX paper is compared with the other RHIC experiment and the CERN, SPS results. Transverse momentum of photons are measured in the electro-magnetic calorimeter (EMCal) and preliminary results are presented. Particle identification is made by a time of flight (TOF) detector and the results show clear separation of the charged hadrons from each other.

356. Measurement of the high energy two-body deuteron photodisintegration differential cross section

Author

S. A. Wood, H. C. Fenker, Pete Markowitz, K. McIlhany, Thomas O'Neill, D. J. Mack, Raphael Noel Tieulent, R. J. Holt, X. Jiang, Stephen Avery, D. F. Geesaman, H. P. Blok, Paul Gueye, Alan M. Nathan, E. R. Kinney, V. Ziskin, Dipanwita Dutta, L. Cole, Wolfgang Lorenzon, F. Xiong, C. E. Keppel, Haiyan Gao, B. D. Fox, J. Reinhold, S. Stepanyan, G. Niculescu, P. G. Roos, M. Harvey, A. Bruell, Douglas H Beck, H. Breuer, Arijit Saha, M. A. Miller, L. G. Tang, R. Sawafta, R. V. Cadman, M. Bouwhuis, B. Mueller, S. F. Pate, H. Mkrtchyan, D. Potterveld, A. Ahmidouch, Y. Liang, I. Niculescu, John Arrington, S. Strauch, Ronald Gilman, M. Zeier, E. Rollinde, V. Papavassiliou, L. Yuan, W. F. Vulcan, N. S. Chant, A. Uzzle, Ronald Ransome, J. H. Mitchell, E. Segbefia, L. Gan, Charles Glashausser, J. W. Martin, R. B. Piercey, D. Meekins, H. E. Jackson, W. U. Boeglin, V. Tadevosyan, A. J. Sarty, Ross Milner, M. Sutter, J. A. Dunne, P. Bosted, K. Garrow, A. Lung, Rolf Ent, B. Zihlmann, T. Shin, D. S. Brown, A. Gasparian, A. Cochran, C. Bochna, C. S. Armstrong, D. McKee, O. K. Baker, Donal Day, S. Danagoulian, R. D. Carlini, E. Schulte, David Gaskell, R. Asaturyan, and (Astro)-Particles Physics

Subjects

Physics, Nuclear reaction, Particle physics, Astrophysics::High Energy Astrophysical Phenomena, Hadron, General Physics and Astronomy, Particle accelerator, Elementary particle, law.invention, Baryon, Nuclear physics, law, Photodisintegration, Neutron, Nuclear Experiment, Nucleon

Abstract

The first measurements of the d(gamma,p)n differential cross section at forward angles and photon energies above 4 GeV were performed at the Thomas Jefferson National Accelerator Facility (JLab). The results indicate evidence of an angular dependent scaling threshold. Results at straight theta(cm) = 37 degrees are consistent with the constituent counting rules for E(gamma) greater, similar 4 GeV, while those at 70 degrees are consistent with the constituent counting rules for E(gamma) greater, similar 1.5 GeV.

357. Reply to ‘‘Comment on ‘Properties of intermediate width structure inC12(12C,12C)12C (02+)’ ’’

Author

A. H. Wuosmaa, R. W. Zurmühle, P. H. Kutt, and S. F. Pate

Subjects

Physics, Nuclear reaction, Nuclear and High Energy Physics, Angular momentum, Scattering, Structure (category theory), Computer Science::Computation and Language (Computational Linguistics and Natural Language and Speech Processing), Inelastic scattering, Quantum mechanics, High Energy Physics::Experiment, Point (geometry), Atomic physics, Legendre polynomials, Spin-½

Abstract

We point out some of the ambiguities inherent in the phase-shift analysis of our inelastic scattering data.

Published

1989