DOCSLIB.ORG

Cumulative Author Index (Print)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Cumulative Author Index (Print) PHYSICAL REVIEW D VOLUME 66, NUMBER 12 15 DECEMBER 2002 Cumulative Author Index All authors of papers published in this volume are listed alphabetically. Full titles are included in each ®rst author's entry. The letters (R), (BR), (C), or (E) following the article number indicate that a paper is a Rapid Communication, a Brief Report, a Comment, or an Erratum, respectively. Aarts, Gert, Daria Ahrensmeier, Rudolf Baier, JuÈrgen Berges, and ͑see Abe, Kenji͒ D 66, 032009͑1͒ Julien Serreau Ð Far-from-equilibrium dynamics with broken Abe, R. Ð ͑see Abe, K.͒ D 66, 032007͑1͒ symmetries from the 1/N expansion of the 2PI effective action. Abe, T. Ð ͑see Abe, K.͒ D 66, 032007͑1͒ D 66, 045008͑15͒ ͑see Abe, K.͒ D 66, 071102͑R͒͑1͒ Abada, A., D. BecÂirevicÂ, Ph. Boucaud, G. Herdoiza, J. P. Leroy, A. ͑see Abe, Kenji͒ D 66, 032009͑1͒ Le Yaouanc, O. PeÁne, and J. RodrõÂguez-Quintero Ð First ͑see Abe, Koya͒ D 66, 052001͑1͒ lattice QCD estimate of the gD*D␲ coupling. D 66, 074504͑1͒ ͑see Abe, Koya͒ D 66, 079905͑E͒͑1͒ Abada, Asmaa, Gautam Bhattacharyya, and Marta Losada Ð General ͑see Casey, B. C. K.͒ D 66, 092002͑1͒ analysis with trilinear and bilinear R-parity violating couplings in ͑see Gabyshev, N.͒ D 66, 091102͑R͒͑1͒ the light of recent SNO data. D 66, 071701͑R͒͑1͒ Abe, Y. Ð ͑see Teshima, T.͒ D 66, 093011͑1͒ Abazajian, Kevork N., John F. Beacom, and Nicole F. Bell Abolins, M. Ð ͑see Abazov, V. M.͒ D 66, 012001͑1͒ Ð Stringent constraints on cosmological neutrino-antineutrino ͑see Abazov, V. M.͒ D 66, 032008͑1͒ asymmetries from synchronized ¯avor transformation. D 66, 013008͑1͒ ͑see Abazov, V. M.͒ D 66, 112001͑1͒ and George M. Fuller Ð Bulk QCD thermodynamics Abramov, V. Ð ͑see Abazov, V. M.͒ D 66, 012001͑1͒ and sterile neutrino dark matter. D 66, 023526͑15͒ ͑see Abazov, V. M.͒ D 66, 032008͑1͒ Abazov, V. M. et al. ͑DO” Collaboration͒ Ð Improved W boson mass ͑see Abazov, V. M.͒ D 66, 112001͑1͒ measurement with the DO” detector. D 66, 012001͑1͒ Abrams, D. et al. ͑CDMS Collaboration͒ Ð Exclusion limits on the et al. ͑DO” Collaboration͒ Ð Direct measurement of the W boson WIMP-nucleon cross section from the Cryogenic Dark Matter decay width. D 66, 032008͑1͒ Search. D 66, 122003͑15͒ et al. ͑DO” Collaboration͒ Ð Search for minimal supergravity in Abrams, G. S. Ð ͑see Aubert, B.͒ D 66, 032003͑1͒ single-electron events with jets and large missing transverse Abreu, E. M. C., A. de Souza Dutra, and C. Wotzasek Ð New energy in ppÅ collisions at ͱsϭ1.8 TeV. D 66, 112001͑1͒ approaches in W gravities. D 66, 105008͑15͒ Abbott, B. Ð ͑see Abazov, V. M.͒ D 66, 012001͑1͒ Accioly, A. and H. Blas Ð Exact Foldy-Wouthuysen transformation for ͑see Abazov, V. M.͒ D 66, 032008͑1͒ real spin-0 particle in curved space. D 66, 067501͑15͒ ͑see Abazov, V. M.͒ D 66, 112001͑1͒ Acharya, B. S. Ð ͑see Abazov, V. M.͒ D 66, 012001͑1͒ Abdalla, E., K. H. C. Castello-Branco, and A. Lima-Santos ͑see Abazov, V. M.͒ D 66, 032008͑1͒ Ð Support of dS/CFT correspondence from space-time perturbations. ͑see Abazov, V. M.͒ D 66, 112001͑1͒ D 66, 104018͑15͒ Achasov, M. N., V. M. Aulchenko, K. I. Beloborodov, A. V. Abdalla, M. C. B., A. L. Gadelha, and I. V. Vancea Ð SU͑1,1͒ Berdyugin, A. G. Bogdanchikov, A. V. Bozhenok, A. D. Bukin, D. thermal group of bosonic strings and D-branes. D 66, 065005͑15͒ A. Bukin, S. V. Burdin, T. V. Dimova, V. P. Druzhinin, V. B. Abdesselam, A. Ð ͑see Abazov, V. M.͒ D 66, 012001͑1͒ Golubev, V. N. Ivanchenko, A. A. Korol, S. V. Koshuba, I. N. ͑see Abazov, V. M.͒ D 66, 032008͑1͒ Nesterenko, E. V. Pakhtusova, A. A. Polunin, A. A. Salnikov, ͑see Abazov, V. M.͒ D 66, 112001͑1͒ S. I. Serednyakov, V. V. Shary, Yu. M. Shatunov, V. A. Sidorov, Z. Abe, Hiroyuki and Tomohiro Inagaki Ð Schwinger-Dyson analysis of K. Silagadze, A. N. Skrinsky, A. G. Skripkin, Yu. V. Usov, ϩ Ϫ ϩ Ϫ dynamical symmetry breaking on a brane with bulk Yang-Mills and A. V. Vasiljev Ð Study of the process e e →␲ ␲ ␲0 in the theory. D 66, 085001͑15͒ energy region ͱs from 0.98 to 1.38 GeV. D 66, 032001͑1͒ Abe, K. et al. ͑Belle Collaboration͒ Ð Observation of mixing-induced AchuÂcarro, A., A. C. Davis, M. Pickles, and J. Urrestilla Ð Vortices CP violation in the neutral B meson system. D 66, 032007͑1͒ in theories with ¯at directions. D 66, 105013͑15͒ et al. ͑Belle Collaboration͒ Ð Improved measurement of mixing- Acosta, D. et al. ͑CDF Collaboration͒ Ð Search for new physics in induced CP violation in the neutral B meson system. photon-lepton events in ppÅ collisions at ͱsϭ1.8 TeV. D 66, 071102͑R͒͑1͒ D 66, 012004͑1͒ ͑see Abe, K.͒ D 66, 032007͑1͒ et al. ͑CDF Collaboration͒ Ð Measurement of the ratio of b ͑see Abe, K.͒ D 66, 071102͑R͒͑1͒ quark production cross sections in Åpp collisions at ͱs ͑see Aubert, B.͒ D 66, 032003͑1͒ ϭ630 GeV and ͱsϭ1800 GeV. D 66, 032002͑1͒ ͑see Casey, B. C. K.͒ D 66, 092002͑1͒ et al. ͑CDF Collaboration͒ Ð Branching ratio measurements of ϩ ͑see Gabyshev, N.͒ D 66, 091102͑R͒͑1͒ exclusive B decays to charmonium with the Collider Detector ͑see Gabyshev, N.͒ D 66, 091102͑R͒͑1͒ at Fermilab. D 66, 052005͑1͒ Abe, Kenji et al. ͑SLD Collaboration͒ Ð Search for time-dependent et al. ͑CDF Collaboration͒ Ð Cross section for forward J/␺ 0 0 Ϯ Bs -Bs oscillations using exclusively reconstructed Ds mesons. production in ppÅ collisions at ͱsϭ1.8 TeV. D 66, 092001͑1͒ D 66, 032009͑1͒ et al. ͑CDF Collaboration͒ Ð Search for radiative b-hadron ͑see Abe, Koya͒ D 66, 052001͑1͒ decays in ppÅ collisions at ͱsϭ1.8 TeV. D 66, 112002͑1͒ ͑see Abe, Koya͒ D 66, 079905͑E͒͑1͒ Adachi, I. Ð ͑see Abe, K.͒ D 66, 032007͑1͒ Abe, Koya et al. ͑SLD Collaboration͒ Ð Improved study of the ͑see Abe, K.͒ D 66, 071102͑R͒͑1͒ ϩ Ϫ structure of e e →bbÅ g events and limits on the anomalous ͑see Casey, B. C. K.͒ D 66, 092002͑1͒ chromomagnetic coupling of the b quark. D 66, 052001͑1͒ ͑see Gabyshev, N.͒ D 66, 091102͑R͒͑1͒ et al. ͑SLD Collaboration͒ Ð Erratum: Measurement of the b- Adam, I. Ð ͑see Abe, Kenji͒ D 66, 032009͑1͒ 0 quark fragmentation function in Z decays ͓Phys. Rev. D 65, ͑see Abe, Koya͒ D 66, 052001͑1͒ 092006 ͑2002͔͒.D 66, 079905͑E͒͑1͒ ͑see Abe, Koya͒ D 66, 079905͑E͒͑1͒ 66 i ii CUMULATIVE AUTHOR INDEX 66 ͑see Aubert, B.͒ D 66, 032003͑1͒ Akerib, D. S. Ð ͑see Abrams, D.͒ D 66, 122003͑15͒ Adam, N. E. Ð ͑see Ahmed, S.͒ D 66, 031101͑R͒͑1͒ Akeroyd, A. G., S. Baek, Gi-Chol Cho, and K. Hagiwara Ð On the 0 ͑see Athar, S. B.͒ D 66, 052003͑1͒ possibility of a very light A at low tan ␤ in the minimal ͑see Benslama, K.͒ D 66, 077101͑BR͒͑1͒ supersymmetric standard model. D 66, 037702͑BR͒͑1͒ ͑see Chen, S.͒ D 66, 071101͑R͒͑1͒ Akimoto, H. Ð ͑see Abe, Kenji͒ D 66, 032009͑1͒ ͑see Dytman, S. A.͒ D 66, 091101͑R͒͑1͒ ͑see Abe, Koya͒ D 66, 052001͑1͒ ͑see Metreveli, Z.͒ D 66, 052002͑1͒ ͑see Abe, Koya͒ D 66, 079905͑E͒͑1͒ Adams, D. L. Ð ͑see Abazov, V. M.͒ D 66, 012001͑1͒ ͑see Acosta, D.͒ D 66, 012004͑1͒ ͑see Abazov, V. M.͒ D 66, 032008͑1͒ ͑see Acosta, D.͒ D 66, 032002͑1͒ ͑see Abazov, V. M.͒ D 66, 112001͑1͒ ͑see Acosta, D.͒ D 66, 052005͑1͒ Adams, David H. Ð ͑see Kamleh, Waseem͒ D 66, 014501͑1͒ ͑see Acosta, D.͒ D 66, 092001͑1͒ Adams, M. Ð ͑see Abazov, V. M.͒ D 66, 012001͑1͒ ͑see Acosta, D.͒ D 66, 112002͑1͒ ͑see Abazov, V. M.͒ D 66, 032008͑1͒ Akopian, A. Ð ͑see Acosta, D.͒ D 66, 012004͑1͒ ͑see Abazov, V. M.͒ D 66, 112001͑1͒ Akushevich, I. Ð ͑see Afanasev, A.͒ D 66, 074004͑1͒ Adib, Artur B., Marcelo Gleiser, and Carlos A. S. Almeida Alam, M. S. Ð ͑see Ahmed, S.͒ D 66, 031101͑R͒͑1͒ Ð Long-lived oscillons from asymmetric bubbles: Existence and ͑see Athar, S. B.͒ D 66, 052003͑1͒ stability. D 66, 085011͑15͒ ͑see Benslama, K.͒ D 66, 077101͑BR͒͑1͒ Adye, T. Ð ͑see Aubert, B.͒ D 66, 032003͑1͒ ͑see Chen, S.͒ D 66, 071101͑R͒͑1͒ Afanasev, A., I. Akushevich, V. Burkert, and K. Joo Ð QED radiative ͑see Dytman, S. A.͒ D 66, 091101͑R͒͑1͒ corrections in processes of exclusive pion electroproduction. ͑see Metreveli, Z.͒ D 66, 052002͑1͒ D 66, 074004͑1͒ Albert, J. Ð ͑see Aubert, B.͒ D 66, 032003͑1͒ Affolder, T. Ð ͑see Acosta, D.͒ D 66, 012004͑1͒ Albrecht, Andreas Ð ͑see Skordis, Constantinos͒ D 66, 043523͑15͒ ͑see Acosta, D.͒ D 66, 032002͑1͒ Albrow, M. G. Ð ͑see Acosta, D.͒ D 66, 012004͑1͒ ͑see Acosta, D.͒ D 66, 052005͑1͒ ͑see Acosta, D.͒ D 66, 032002͑1͒ ͑see Acosta, D.͒ D 66, 092001͑1͒ ͑see Acosta, D.͒ D 66, 052005͑1͒ ͑see Acosta, D.͒ D 66, 112002͑1͒ ͑see Acosta, D.͒ D 66, 092001͑1͒ Aglietti, U. and G. Ricciardi Ð Approximate next-to-next-to-leading- ͑see Acosta, D.͒ D 66, 112002͑1͒ order threshold resummation in heavy ¯avor decays. Albuquerque, Ivone F. M., Jodi Lamoureux, and George F. Smoot D 66, 074003͑1͒ Ð Neutrino telescopes' sensitivity to dark matter. D 66, 125006͑15͒ Aguilar-Arevalo, Alexis A.
Load more

Recommended publications
  • Supergravity and Its Legacy Prelude and the Play
    Supergravity and its Legacy Prelude and the Play Sergio FERRARA (CERN – LNF INFN) Celebrating Supegravity at 40 CERN, June 24 2016 S. Ferrara - CERN, 2016 1 Supergravity as carved on the Iconic Wall at the «Simons Center for Geometry and Physics», Stony Brook S. Ferrara - CERN, 2016 2 Prelude S. Ferrara - CERN, 2016 3 In the early 1970s I was a staff member at the Frascati National Laboratories of CNEN (then the National Nuclear Energy Agency), and with my colleagues Aurelio Grillo and Giorgio Parisi we were investigating, under the leadership of Raoul Gatto (later Professor at the University of Geneva) the consequences of the application of “Conformal Invariance” to Quantum Field Theory (QFT), stimulated by the ongoing Experiments at SLAC where an unexpected Bjorken Scaling was observed in inclusive electron- proton Cross sections, which was suggesting a larger space-time symmetry in processes dominated by short distance physics. In parallel with Alexander Polyakov, at the time in the Soviet Union, we formulated in those days Conformal invariant Operator Product Expansions (OPE) and proposed the “Conformal Bootstrap” as a non-perturbative approach to QFT. S. Ferrara - CERN, 2016 4 Conformal Invariance, OPEs and Conformal Bootstrap has become again a fashionable subject in recent times, because of the introduction of efficient new methods to solve the “Bootstrap Equations” (Riccardo Rattazzi, Slava Rychkov, Erik Tonni, Alessandro Vichi), and mostly because of their role in the AdS/CFT correspondence. The latter, pioneered by Juan Maldacena, Edward Witten, Steve Gubser, Igor Klebanov and Polyakov, can be regarded, to some extent, as one of the great legacies of higher dimensional Supergravity.
    [Show full text]
  • Subnuclear Physics: Past, Present and Future
    Subnuclear Physics: Past, Present and Future International Symposium 30 October - 2 November 2011 – The purpose of the Symposium is to discuss the origin, the status and the future of the new frontier of Physics, the Subnuclear World, whose first two hints were discovered in the middle of the last century: the so-called “Strange Particles” and the “Resonance #++”. It took more than two decades to understand the real meaning of these two great discoveries: the existence of the Subnuclear World with regularities, spontaneously plus directly broken Symmetries, and totally unexpected phenomena including the existence of a new fundamental force of Nature, called Quantum ChromoDynamics. In order to reach this new frontier of our knowledge, new Laboratories were established all over the world, in Europe, in USA and in the former Soviet Union, with thousands of physicists, engineers and specialists in the most advanced technologies, engaged in the implementation of new experiments of ever increasing complexity. At present the most advanced Laboratory in the world is CERN where experiments are being performed with the Large Hadron Collider (LHC), the most powerful collider in the world, which is able to reach the highest energies possible in this satellite of the Sun, called Earth. Understanding the laws governing the Space-time intervals in the range of 10-17 cm and 10-23 sec will allow our form of living matter endowed with Reason to open new horizons in our knowledge. Antonino Zichichi Participants Prof. Werner Arber H.E. Msgr. Marcelo Sánchez Sorondo Prof. Guido Altarelli Prof. Ignatios Antoniadis Prof. Robert Aymar Prof. Rinaldo Baldini Ferroli Prof.
    [Show full text]
  • Field Theory Insight from the Ads/CFT Correspondence
    Field theory insight from the AdS/CFT correspondence Daniel Z.Freedman1 and Pierre Henry-Labord`ere2 1Department of Mathematics and Center for Theoretical Physics Massachusetts Institute of Technology, Cambridge, MA 01239 E-mail: [email protected] 2LPT-ENS, 24, rue Lhomond F-75231 Paris cedex 05, France E-mail: [email protected] ABSTRACT A survey of ideas, techniques and results from d=5 supergravity for the conformal and mass-perturbed phases of d=4 N =4 Super-Yang-Mills theory. arXiv:hep-th/0011086v2 29 Nov 2000 1 Introduction The AdS/CF T correspondence [1, 20, 11, 12] allows one to calculate quantities of interest in certain d=4 supersymmetric gauge theories using 5 and 10-dimensional supergravity. Mirac- ulously one gets information on a strong coupling limit of the gauge theory– information not otherwise available– from classical supergravity in which calculations are feasible. The prime example of AdS/CF T is the duality between =4 SYM theory and D=10 N Type IIB supergravity. The field theory has the very special property that it is ultraviolet finite and thus conformal invariant. Many years of elegant work on 2-dimensional CF T ′s has taught us that it is useful to consider both the conformal theory and its deformation by relevant operators which changes the long distance behavior and generates a renormalization group flow of the couplings. Analogously, in d=4, one can consider a) the conformal phase of =4 SYM N b) the same theory deformed by adding mass terms to its Lagrangian c) the Coulomb/Higgs phase.
    [Show full text]
  • Graphs and Patterns in Mathematics and Theoretical Physics, Volume 73
    http://dx.doi.org/10.1090/pspum/073 Graphs and Patterns in Mathematics and Theoretical Physics This page intentionally left blank Proceedings of Symposia in PURE MATHEMATICS Volume 73 Graphs and Patterns in Mathematics and Theoretical Physics Proceedings of the Conference on Graphs and Patterns in Mathematics and Theoretical Physics Dedicated to Dennis Sullivan's 60th birthday June 14-21, 2001 Stony Brook University, Stony Brook, New York Mikhail Lyubich Leon Takhtajan Editors Proceedings of the conference on Graphs and Patterns in Mathematics and Theoretical Physics held at Stony Brook University, Stony Brook, New York, June 14-21, 2001. 2000 Mathematics Subject Classification. Primary 81Txx, 57-XX 18-XX 53Dxx 55-XX 37-XX 17Bxx. Library of Congress Cataloging-in-Publication Data Stony Brook Conference on Graphs and Patterns in Mathematics and Theoretical Physics (2001 : Stony Brook University) Graphs and Patterns in mathematics and theoretical physics : proceedings of the Stony Brook Conference on Graphs and Patterns in Mathematics and Theoretical Physics, June 14-21, 2001, Stony Brook University, Stony Brook, NY / Mikhail Lyubich, Leon Takhtajan, editors. p. cm. — (Proceedings of symposia in pure mathematics ; v. 73) Includes bibliographical references. ISBN 0-8218-3666-8 (alk. paper) 1. Graph Theory. 2. Mathematics-Graphic methods. 3. Physics-Graphic methods. 4. Man• ifolds (Mathematics). I. Lyubich, Mikhail, 1959- II. Takhtadzhyan, L. A. (Leon Armenovich) III. Title. IV. Series. QA166.S79 2001 511/.5-dc22 2004062363 Copying and reprinting. Material in this book may be reproduced by any means for edu• cational and scientific purposes without fee or permission with the exception of reproduction by services that collect fees for delivery of documents and provided that the customary acknowledg• ment of the source is given.
    [Show full text]
  • Twenty Years of the Weyl Anomaly
    CTP-TAMU-06/93 Twenty Years of the Weyl Anomaly † M. J. Duff ‡ Center for Theoretical Physics Physics Department Texas A & M University College Station, Texas 77843 ABSTRACT In 1973 two Salam prot´eg´es (Derek Capper and the author) discovered that the conformal invariance under Weyl rescalings of the metric tensor 2 gµν(x) Ω (x)gµν (x) displayed by classical massless field systems in interac- tion with→ gravity no longer survives in the quantum theory. Since then these Weyl anomalies have found a variety of applications in black hole physics, cosmology, string theory and statistical mechanics. We give a nostalgic re- view. arXiv:hep-th/9308075v1 16 Aug 1993 CTP/TAMU-06/93 July 1993 †Talk given at the Salamfest, ICTP, Trieste, March 1993. ‡ Research supported in part by NSF Grant PHY-9106593. When all else fails, you can always tell the truth. Abdus Salam 1 Trieste and Oxford Twenty years ago, Derek Capper and I had embarked on our very first post- docs here in Trieste. We were two Salam students fresh from Imperial College filled with ideas about quantizing the gravitational field: a subject which at the time was pursued only by mad dogs and Englishmen. (My thesis title: Problems in the Classical and Quantum Theories of Gravitation was greeted with hoots of derision when I announced it at the Cargese Summer School en route to Trieste. The work originated with a bet between Abdus Salam and Hermann Bondi about whether you could generate the Schwarzschild solution using Feynman diagrams. You can (and I did) but I never found out if Bondi ever paid up.) Inspired by Salam, Capper and I decided to use the recently discovered dimensional regularization1 to calculate corrections to the graviton propaga- tor from closed loops of massless particles: vectors [1] and spinors [2], the former in collaboration with Leopold Halpern.
    [Show full text]
  • Supergravity at 40: Reflections and Perspectives(∗)
    RIVISTA DEL NUOVO CIMENTO Vol. 40, N. 6 2017 DOI 10.1393/ncr/i2017-10136-6 ∗ Supergravity at 40: Reflections and perspectives( ) S. Ferrara(1)(2)(3)andA. Sagnotti(4) (1) Theoretical Physics Department, CERN CH - 1211 Geneva 23, Switzerland (2) INFN - Laboratori Nazionali di Frascati - Via Enrico Fermi 40 I-00044 Frascati (RM), Italy (3) Department of Physics and Astronomy, Mani L. Bhaumik Institute for Theoretical Physics U.C.L.A., Los Angeles CA 90095-1547, USA (4) Scuola Normale Superiore e INFN - Piazza dei Cavalieri 7, I-56126 Pisa, Italy received 15 February 2017 Dedicated to John H. Schwarz on the occasion of his 75th birthday Summary. — The fortieth anniversary of the original construction of Supergravity provides an opportunity to combine some reminiscences of its early days with an assessment of its impact on the quest for a quantum theory of gravity. 280 1. Introduction 280 2. The early times 282 3. The golden age 283 4. Supergravity and particle physics 284 5. Supergravity and string theory 286 6. Branes and M-theory 287 7. Supergravity and the AdS/CFT correspondence 288 8. Conclusions and perspectives ∗ ( ) Based in part on the talk delivered by S.F. at the “Special Session of the DISCRETE2016 Symposium and the Leopold Infeld Colloquium”, in Warsaw, on December 1 2016, and on a joint CERN Courier article. c Societ`a Italiana di Fisica 279 280 S. FERRARA and A. SAGNOTTI 1. – Introduction The year 2016 marked the fortieth anniversary of the discovery of Supergravity (SGR) [1], an extension of Einstein’s General Relativity [2] (GR) where Supersymme- try, promoted to a gauge symmetry, accompanies general coordinate transformations.
    [Show full text]
  • Personal Recollections of the Early Days Before and After the Birth of Supergravity
    Personal recollections of the early days before and after the birth of Supergravity Peter van Nieuwenhuizen I March 29, 1976: Dan Freedman, Sergio Ferrara and I submit first paper on Supergravity to Physical Review D. I April 28: Stanley Deser and Bruno Zumino: elegant reformulation that stresses the role of torsion. I June 2, 2016 at 1:30pm: 5500 papers with Supergravity in the title have appeared, and 15000 dealing with supergravity. I Supergravity has I led to the AdS/CFT miracle, and I made breakthroughs in longstanding problems in mathematics. I Final role of supergravity? (is it a solution in search of a problem?) I 336 papers in supergravity with 126 collaborators I Now: many directions I can only observe in awe from the sidelines I will therefore tell you my early recollections and some anecdotes. I will end with a new research program that I am enthusiastic about. In 1972 I was a Joliot Curie fellow at Orsay (now the Ecole Normale) in Paris. Another postdoc (Andrew Rothery from England) showed me a little book on GR by Lawden.1 I was hooked. That year Deser gave lectures at Orsay on GR, and I went with him to Brandeis. In 1973, 't Hooft and Veltman applied their new covariant quantization methods and dimensional regularization to pure gravity, using the 't Hooft lemma (Gilkey) for 1-loop divergences and the background field formalism of Bryce DeWitt. They found that at one loop, pure gravity was finite: 1 2 2 ∆L ≈ αRµν + βR = 0 on-shell. But what about matter couplings? 1\An Introduction to Tensor Calculus and Relativity".
    [Show full text]
  • Physics & Astronomy – Our Community
    Peter Koch, updated 26 March 2006 from 13 September 2005 Physics & Astronomy – Our Community Graduate student degrees awarded Stony Brook is one of the leading universities in number of physics Ph.D. degrees granted. At Stony Brook in 2003-4: 32 PhDs in 2004-5: 21 PhDs plus 3 more in August Graduate students in 2005-6 (2nd large class in a row) 41 graduate students entered last year 18 US, 13 Asia, 9 Europe, 1 Mideast 30 male, 11 female 36 for PhD program 3 Würzburg exchange students for MA degree 2 for Masters of Science in Instrumentation We aim for a somewhat smaller entering class this year. Thanks to Sara Lutterbie for slide preparation Thanks to Sara Lutterbie for slide preparation New faculty appointments Michael Zingale, computational astrophysics. Mike’s main research is on Type Ia supernovae, specifically flame instabilities. (He also blows up Type I supernovae in computers.) After a postdoc at the Supernovae Science Center at UC Santa Cruz, Mike joined us as Assistant Professor in January 2006. Three-dimensional reactive RT simulations: (in collaboration with LBL/CCSE) Three-dimensional direct numerical simulations of carbon flames in Type Ia supernovae undergoing the Rayleigh- Taylor instability and the transition to turbulence. New faculty appointments Urs Wiedemann, nuclear theory. Urs’s main research is on the theory of dense QCD matter now being studied in relativistic heavy ion collisions at RHIC at nearby Brookhaven National Laboratory (BNL – co managed by Stony Brook University and Battelle Memorial Institute) and after about 2007 at the LHC at CERN. Fresh from a staff theory position at CERN, Urs joined us as Assistant Professor in January 2006 in a joint position with the RIKEN Institute at BNL.
    [Show full text]
  • On the Hunt for Excited States
    INTERNATIONAL JOURNAL OF HIGH-ENERGY PHYSICS CERN COURIER VOLUME 45 NUMBER 10 DECEMBER 2005 On the hunt for excited states HOMESTAKE DARK MATTER SNOWMASS Future assured for Galactic gamma rays US workshop gets underground lab p5 may hold the key p 17 ready for the ILC p24 www.vectorfields.comi Music to your ears 2D & 3D electromagnetic modellinj If you're aiming for design excellence, demanding models. As a result millions you'll be pleased to hear that OPERA, of elements can be solved in minutes, the industry standard for electromagnetic leaving you to focus on creating modelling, gives you the most powerful outstanding designs. Electron trajectories through a TEM tools for engineering and scientific focussing stack analysis. Fast, accurate model analysis • Actuators and sensors - including Designed for parameterisation and position and NDT customisation, OPERA is incredibly easy • Magnets - ppm accuracy using TOSCA to use and has an extensive toolset, making • Electron devices - space charge analysis it ideal for a wide range of applications. including emission models What's more, its high performance analysis • RF Cavities - eigen modes and single modules work at exceptional levels of speed, frequency response accuracy and stability, even with the most • Motors - dynamic analysis including motion Don't take our word for it - order your free trial and check out OPERA yourself. B-field in a PMDC motor Vector Fields Ltd Culham Science Centre, Abingdon, Oxon, 0X14 3ED, U.K. Tel: +44 (0)1865 370151 Fax: +44 (0)1865 370277 Email: [email protected] Vector Fields Inc 1700 North Famsworth Avenue, Aurora, IL, 60505.
    [Show full text]
  • Supergravity
    Supergravity Parada Prangchaikul, Suranaree University of Technology, Thailand September 6, 2018 Abstract Supergravity theory is an effective theory of M-theory in 11 dimensions (11D), hence the study of supergravity helps us understanding the fundamental theory. In this project, we worked on the construction of supergravity theories in certain conditions and studied the supersymmetry transformations of field contents in the theories. Furthermore, we studied a bosonic sector of matter coupled N = 2 4D supergravity using coset manifold. In conclusion, we obtained N = 1, N = 2 supergravity theories in 4D, 11D supergravity and the special Kahler manifold from the bosonic sector of matter coupled N = 2 4D supergravity written in the coset form G=H. 1 Contents 1 Introduction 3 2 N = 1 D = 4 supergravity 3 3 D = 11 supergravity 4 4 N = 2 D = 4 Supergravity 5 5 The bosonic sector of matter coupled N = 2 D = 4 supergravity 6 6 Future work 8 2 1 Introduction The minimal supergravity in 4 dimension was constructed by [1] in 1976. After that it was generalized in various dimensional spacetimes and numbers of supersymmetries. Then, Cremmer, Julia and Scherk [2] found the mother theory of supergravity, which was the theory in 11 spacetime dimensions. Since D > 11 dimensional theories consist of particles with helicities greater than 2. Therefore, the greatest supergravity theory is the one that lives in 11 dimensions (some physicists might say that supergravity is in its most beautiful form in 11 dimensions). In 1995, Edward Witten [3] found the link between five candidates of string theory which are type I, type IIA, type IIB, SO(32) Heterotic and E8 × E8 Heterotic string theories.
    [Show full text]
  • Curriculum Vitae: Sylvester James Gates, Jr
    Curriculum Vitae: Sylvester James Gates, Jr. Personal Information Date of Birth: December 15, 1950 Place of Birth: Tampa, FL, USA Departmental Address: Brown University Department of Physics Box 1843 Providence, RI 02912 USA Webpage: https://sites.brown.edu/sjgates/ Email Address: [email protected] Undergraduate Education: Massachusetts Institute of Technology, 1969-1973 B.Sc. in Mathematics, M.I.T., June 1, 1973 B.Sc. in Physics, M.I.T., September 12, 1973 Undergraduate Thesis: (Physics) “On the Feasibility of Generating Electricity with a Rijke Tube.” This thesis is an analysis of the acoustical, mechanical, and thermodynamical problems associated with using the Rijke phenomena to generate electricity. Thesis Advisor: Professor K. U. Ingard Graduate Education: Massachusetts Institute of Technology, 1973-1977, Ph.D. Physics, M.I.T., June 6, 1977. Graduate Thesis: “Symmetry Principles in Selected Problems of Field Theory” Doctoral thesis describes an investigation of the uses of symmetry principles in unified models of the Weak and Electromagnetic Interactions and in supersymmetric models. First Ph.D. thesis at MIT on the topic of supersymmetry. Thesis Advisor: Professor J. E. Young Postdoctoral Experience: Research Fellow, California Institute of Technology, 1980-1982, Junior Fellow. Harvard Society of Fellows, Harvard Univ. 1977-1980. Faculty Positions: Faculty Fellow, Watson Institute for International Studies & Public Affairs, Brown University, March 2019 – present Ford Foundation Professor of Physics, Affiliate Professor
    [Show full text]
  • Superfluous Physics
    Superfluous Physics Evan Berkowitz,1, ∗ William Donnelly,2 and Sylvia Zhu3, 4 (Scientists Undertaking Preposterous Etymological Research Collaboration) 1Institut f¨ur Kernphysik and Institute for Advanced Simulation, Forschungszentrum J¨ulich, 54245 J¨ulich Germany 2Perimeter Institute for Theoretical Physics, 31 Caroline St. N. Waterloo, ON, N2L 2Y5, Canada 3Max Planck Institute for Gravitational Physics (Albert Einstein Institute), Callinstraße 38, 30167 Hannover Germany 4Leibniz Universit¨at Hannover, D-30167 Hannover, Germany (Dated: April 1, 2019) A superweapon of modern physics superscribes a wide superset of phenomena, ranging from supernumerary rainbows to superfluidity and even possible supermultiplets. I. INTRODUCTION The questions run too deep For such a simple man Won’t you please, Please tell me what we’ve learned? Supertramp, The Logical Song Supermassive black holes have nonzero supermass, the quantity that couples to N = 1 supergravity, while in theories with more supercharges one may have superdupermassive black holes, and so on. Just as the no-hair theorem tells us that non-rotating black holes can be described as massive and charged, the no-hair supertheorem tell us that non-rotating superheavy black holes can be described as supermassive and supercharged. String theory provides hope to understand how to go beyond the semiclassical limit to describe in detail if and how black holes preserve unitarity, while superstring theory provides hope to understand the unitarity of supermassive black holes. With the recent observation of normal black hole [1–5] and neutron star[6] mergers via gravitational waves by the super-sensitive Advanced LIGO and VIRGO detectors, it is not unreasonable to expect gravitational-wave detections of supernovae of collapsing superstars or violent supermassive black hole astrophysical phenomena are on the horizon or, if you’ll forgive the absurd pun, superhorizon.
    [Show full text]