CLOSING CEREMONY - Springer978-1-4615-3402-0/1.pdf · CLOSING CEREMONY The closing ceremony took...

CLOSING CEREMONY

The closing ceremony took place on Sunday 21st July 1991. The School was

especially honoured this year to have Madame Dirac in attendance at the Closing

Session, at which she presented the Dirac scholarship to Ulf Danielsson.

The Prizes and Scholarships were awarded as specified below.

PRlZES AND SCHOLARSHIPS

• Prize for Best Student awarded to:

WE DANIELSSON, Princeton University, USA.

Matthias NEUBERT, Universitat Heidelberg, Germany.

Ira ROTHSTEIN, University of Maryland, USA.

• Prize for Best Scientific Secretary awarded to:

Pilar HERNANDEZ, CERN, Geneva, Switzerland.

• Twelve Scholarships were open for competition among the participants. They were awarded as follows:

• J.S. BELL Scholarship to: Ira ROTHSTEIN, University of Maryland, USA.

• Patrick M.S. BLACKETT Scholarship to:

Matthias NEUBERT, Universitat Heidelberg, Germany.

• James CHADWICK Scholarship to:

Pilar HERNANDEZ, CERN, Geneva, Switzerland.

• Amos DE-SHALIT Scholarship to:

Erez ETZION, Tel Aviv University, Israel.

• Paul A.M. DIRAC Scholarship to:

WE DANIELSSON, Princeton University, USA.

• Isidor I. RABI Scholarship to:

Doug BORDEN, Stanford Linear Accelerator Center, USA.

399

• Robert HOFSTADTER Scholarship to:

Thomas JUNK, Stanford Linear Accelerator Center, USA.

• Andreij D. SAKHAROV Scholarship to:

Mark POTTERS, Princeton University, USA.

• Jun John SAKURAI Scholarship to:

Zbigniew PLUCIENNIK, Inst. of Theoretical Phys., Warsaw, Poland.

• Gunnar KALLEN Scholarship to:

Anwarl HASAN, World Laboratory and CERN, Geneva, Switzerland.

• Andre LAGARRIGUE Scholarship to: Ujjwal VIKAS, World Laboratory and CERN, Geneva, Switzerland.

• Giulio RACAH Scholarship to: Manjjt KAUR, World Laboratory and CERN, Geneva, Switzerland.

• One EPS Scholarship was awarded to: Jan CZYZEWSKI, Inst. of Physics, Jagellonian Univ., Krakow, Poland.

• Two WFS Scholarships were awarded to: Alexei V. CHIZHOV, Laboratory of Theoretical Physics, Dubna, USSR.

Ahpisit UNGKITCHANUKIT, Phys. Dept., Faculty of Scie., Bangkok, Thailand.

The following participants gave their collaboration in the Scientific Sec

retarial work:

400

Doug BORDEN Alexei V. CHIZHOV Jan CZYZEWSKI Ulf DANIELSSON

Maria Teresa DOVA

EdaESKUT

ErezETZION

Anwarul HASAN

Pilar HERNANDEZ

Mark JOHNSON

Manjjt KAUR

Norair KHALATIAN

AyseKUZUCU

Stephen LAU

Bengt A. LINDHOLM

Rukhsana MALIK Ronan McNULTY

Nars E. MOULAI

Matthias NEUBERT

Muhammad A. NIAZ

Zbigniev PL UCIENNIK

Marc POTTERS

Khalid QURESHI

Ira ROTHSTEIN

Hans-Josef SCHULZE

Ali A. SYED

Patribha VIKAS

Ujjwal VIKAS

Maneesh WADHWA

Xin WU

Professor John Peoples, Director of Fermilab, Madame Margit Dirac, Professor

Heinrich Leutz, Deputy Director of LAA, Professor Antonino Zichichi and Dr. Ulf

Danielsson.

401

PARTICIPANTS

Gianluca ALIMONTI

Guido ALTARELLI

William A. BARLETTA

Knut Steinar BJORKEVOLL

Doug BORDEN

Stefan BORNHOLDT

Paolo BRANCHINI

Dipartimento di Fisica

Universita di Milano

Via Celoria, 16

1-20133 MILANO, Italy

CERN

TH Division

CH-1211 GENEVA 23, Switzerland

Physics Department

UCLA/LLNL

East Avenue P.O. Box 808

LIVERMORE, CA 94550, USA

Physics Department

University of Bergen

Allegaten, 55

N-5007 BERGEN, Norway

S LAC, Bin 43

P.O. Box 4349

STANFORD, CA 94309, USA

DESY

Theory Group

Notkestrasse, 85

D-2000 HAMBURG 52, Germany


Universita di Roma II

Via Orazio Raimondo

1-00173 ROMA, Italy

403

Andrea BRIGNOLE

David BROWN

Riccardo BRUGNERA

Vasile BUZULOIU

Alexei V. CHIZHOV

Luisa CIFARELLI

Jan CZYZEWSKI

Ulf DANIELSSON

Luigi DEL DEBBIO

404


Universita di Padova

Via Marzolo, 8

1-35100 PADOVA, Italy

CERN

PPE Division



Universita di Padova

Via Marzolo, 8

1-35100 PADOVA, Italy

World Laboratory and C ERN


Laboratory of Theoretical Physics

Joint Inst. for Nuclear Research

DUBNA, 141980 USSR

Dipartimento di Scienze Fisiche

Universita di Napoli

Mostra d'Oltremare - Pad. 19

1-80125 NAPOLI, Italy

Institute of Particle Physics

Jagellonian University

Reymonta,4

PL-KRAKOW, Poland

Physics Department

Princeton University

Jadwin Hall - P.O. Box 708

PRINCETON, NJ 08544, USA

INFN- Sezione di Pisa

Via Livornese 582/ A

San Piero a Grado

1-56010 PISA, Italy

Yuri DOKSHITZER

Maria Teresa DOVA

Michael DUFF

Huy Danh DUONG

John ELLIS

EdaESKUT

Erez ETZION

Sergio FERRARA

Emanuele FIANDRINI

Leningrad Inst. of Nuclear Physics

Department of Theoretical Physics

188350 GATCHINA, USSR



Center for Theoretical Physics

Physics Department

Texas A&M University

COLLEGE STATION, TX 77843, USA

Southampton University

Physics Department

Highfield

SOUTHAMPTON, S095NH, UK

CERN

TH Division




School of Physics and Astronomy

Tel Aviv University

69978 TEL AVIV, Israel

Physics Department University of California

405 Hilgard Avenue

LOS ANGELES, CA 90024, USA

and

CERN

TH Division



Universita di Perugia

Via Pascoli

1-06100 PERUGIA, Italy

405

Jeffrey R. FORSHAW

Elisabetta GALLO

Paola GIANOTTI

Fred J. GILMAN

Ferenc GLUCK

Ariel GOO BAR

Andreas GOUGAS

Michel GOURDIN

Thierry GRANIER

406

Physics Department

University of Manchester

MANCHESTER M13 9PL, UK


Universita di Firenze

Largo E. Fermi, 2

1-50125 FIRENZE, Italy

INF N

Sezione di Torino

Via P. Giuria, 1

1-10125 TORINO, Italy

S S C Laboratory

2550 Beckleymeade Avenue

DALLAS, TX 75237, USA

Central Res. Inst. for Physics

P.O. Box 49

H-1525 BUDAPEST, Hungary

Physics Department

University of Stockholm

Vanadisvagen 9

S-11346 STOCKHOLM, Sweden

CERN

PPE Division


Dept. de Physique

Universite P. et M. Curie

4 Place Jussieu

F-75252 PARIS, France

DSM / DPhPE / SEPh

CEN - Saclay

F-~1191 GIF-sur-YVETTE, France

Reinhold J. GUTH

Anwarul HASAN

Pilar HERNANDEZ

Vidyut JAIN

Mark JOHNSON

Thomas JUNK

William A. KAUFMAN

Manjjt KAUR

Norair KHALATYAN

Valery KHOZE

Werner-Heisenberg Inst. fur Physik

Max-Planck-Institut fUr Physik und Astrophysik

Fohringer Ring 6

D-8000 MUNCHEN 40, Germany



CERN

TH Division


Werner-Heisenberg Inst. fUr Physik

Max-Planck-Institut fUr Physik und Astrophysik

Fohringer Ring 6

D-8000 MUNCHEN 40, Germany

Physics Department

University of North Carolina

CB 3255

CHAPEL HILL, NC 27399, USA

SLAC - Bin 96

2575 Sand Hill Road

MENLO PARK, CA 94309, USA

Randall Laboratory of Physics

University of Michigan

ANN ARBOR, MI 48109, USA



Yerevan Physics Institute

Alikhanian Brothers St. 2

YEREVAN, 375036 Armenia, USSR




407

Bruce James KING

Ralph KRETSCHMER

AyseKUZUCU

Stephen LAU

Heinrich LEUTZ

Giuseppe LEVI

Bengt-Ake LINDHOLM

Eligio LISI

Sergio LUPIA

408

Fermi National Accelerator Lab.

P.O. Box 500

BATAVIA, IL 60510, USA

Fachbereich Physik

Universitat Siegen

Adolf-Reichwein-Strasse 2

D-5900 SIEGEN, Germany



Physics Department

University of North Carolina

CB 3255 - Phillips Hall

CHAPEL HILL, :NC 27399, USA

CERN

PPE Division - LAA


INFN-Sezione di Perugia

Via Pascoli

1-06100 PERUGIA, Italy

Physics Department


Vanadisvagen. 9



Universita di Bari

Via Amendola, 173

1-70100 BARI, Italy

Dipartimento di Fisica Teorica

Universita di Torino

Via P. Giuria, 1


Carmen MAIDANTCHIK

Rukhsana MALIK

Ronan McNULTY

Mario MIRAGLIUOLO

Nasr-Eddine MOULAI

Matthias NEUBERT

Muhammad Arif NIAZ

Lev B. OKUN

Orlando OLIVEIRA

Nazife OZDES

Elena PAPAGEORGIU

World Laboratory and C ERN CH-1211 GENEVA 23, Switzerland

World Laboratory and C ERN CH-1211 GENEVA 23, Switzerland

Physics Department

University of Liverpool

Oliver Lodge Lab., Oxford Street

LIVERPOOL L69 EBX, UK

Dipartimento di Scienze Fisiche Universita degli Studi di Napoli





Institut fiir Theoretische Physik

Universitat Heidelberg

Philosophenweg 16

D-6900 HEIDELBERG, Germany



ITEP B. Cheremushkinskaya ul. 89

117259 MOSCOW, USSR

Departamento de Fisica

Fac. de Ciencias e Tec. Univ. de Coimbra

P-3000 COIMBRA, Portugal



Rutherford Appleton Laboratory

High Energy Physics Theory

Chilton

DIDCOT, OXU ORA, UK

409

Youngchul PARK

Stefano PASSAGGIO

Luca PASSALACQUA

Massimo PASSERA

Roberto PECCEI

John PEOPLES

Donald H. PERKINS

Zbigniew PLUCIENNIK

Marc POTTERS

Khalid QURESHI

410

Physics Department

University of California

SANTA BARBARA, CA 93106, USA


Universita. di Genova and INFN-Sezione di Gen

Via Dodecaneso, 33

1-16146 GENOVA, Italy

Lab. Naz. di Frascati-(LNF)

1st. Naz. di Fisica Nucleare-(INFN)

Via E. Fermi, 40

1-00044 FRASCATI, Italy

INFN-Sezione di Torino

Via P. Giuria, 1


Physics Department

University of California

405 Hilgard Avenue

LOS ANGELES, CA 90024, USA

FNAL

P.O. Box 500 - Wilson Road

BATAVIA, IL 60501, USA

Nuclear Physics Laboratory

University of Oxford

Keble Road

OXFORD,OXI3RH,UK

Institute of Theoretical Physics

Warsaw University

Hoza,69

PL-00-681 WARSAW, Poland


Physics Department

P.O. Box 708

PRINCETON, NJ 08544, USA



Renzo RAGAZZON

Patrick ROBERTS

Ira ROTHSTEIN

Norma SANCHEZ

Pietro SANTORELLI

Hans-Josef SCHULZE

Michael SEYMOUR

Yuly SHABELSKI

Chidambaram SIV ARAM

Dipartimento di Fisica Teorica

Universita degli Studi di Trieste

Strada Costiera, 11

Miramare

1-34014 TRIESTE, Italy

Institute of Theoretical Physic

Elementary Particle Physics

S-41296 GOTEBORG, Sweden

Dept. of Physics and Astronomy

University of Maryland

COLLEGE PARK, MD 20742, USA

Observatoire de Paris

Section d'Astrophysique

5, Place Jules Janssen

F-95125 MEUDON, France

Dipartimento di Scienze Fisiche

Universita degli Studi di Napoli



Inst. fiir Theoretische Physik

Universitat Heidelberg

Philosophenweg 19

D-6900 HEIDELBERG, Germany

Physics Department

Cambridge University

CAMBRIDGE CB3 OHE, UK




Dept. of Physics and Astrophysics

Indian Astrophysical Institute

560034 BANGALORE, India

411

Vasilios SPANOS

Aly Aamer SYED

Tommaso TABARELLI

William TRlSCHUK

Ahpisit UNGKITCHANUKIT

Pratibha VIKAS

Ujjwal VIKAS

Maneesh WADHWA

Zhao Min WANG

Daniel WESELKA

Mark WEXLER

412

Institute of Nuclear Physics

NRPS "Demokritos"

GR-1531O ATHENS, Greece




Universita degli Studi di Milano

Via Celoria, 16

1-20133 MILANO, Italy

CERN

PPE Division


Physics Department

Faculty of Sciences

Chulalonghorn University

BANGKOK 10330, Thailand









Institut fiir Hochenergiephysik

Osterreichischen Akademie

Nikolsdorfer Gasse 18

A-1050 WIEN, Austria

Physics Department


P.O. Box 708

PRlNCETON, NJ 08544, USA

XinWU

Geraldo XEXEO

Qinghao YE

Quiping ZHANG

Dept. de Physique TMorique

Universite de Geneve

24 Quai Ernest-Ansermet

CH-1211 GENEVA, Switzerland





Physics Department


Vanadisvagen, 9


413

INDEX

Abelian QED. 14 vector potential Am. 171

Acceleration of a particle defined. 3. 12 force other than gravitation. 12

Adiabaticity. 284-285. 292-294 Adler Bell Jackiw anomaly. 96 Antiparticles. mass. 13 Atiyah Singer theorem. 99

B*. lowering. 380 B + L violations. 112. 113

amplitude. Sphaleron. 116-118 high energy. 120 neutrino activation. 125 pp co11isons. 123 size. 115-117 valley approach. 121. 128 weak interactions (coupling

theories). 89. 97-99. 102 B production. Tevatron. 246 Barden's identity. e-vacua. 96 Baryons

numbers high temperatures. 123 universe. 85

BB mixing. 336-339 Beamstrahlung

compared with synchrotron. 382-383

defined. 381 plasma lens. 322

Beryllium. neutrinos. 295. 302 Bessel function. modified. 31 Beta decay

barrier penetration factor. 251 beta spectrometer. 259 electron spectrum. 251 Kurie plot. 252-254. 257. 269.

277 see also Neutrino physics

Betti numbers. 197. 198 Bianchi identity. 136. 173. 175.

178. 180 Yang-Mills action. 184

Big Bang nucleosynthesis. neutrino physics. 270-271

Bjorken process. 248. 303 Black p-branes. collapse. 202-203 Bogonol'nyi bound. 181 Boltzmann factor. 123. 124

Borel summability. Ae4 • 90. 114. 129

Born term form factor. 27 Boron neutrinos. 295 Bosons

copious. 90 Goldstone boson. 273 mass. one-loop order. 60 massive gauge. 332-333 space-time coordinates. 66 W boson

detection. 323-329 results. 330-331

see also Higgs bosons Bottomonium decays. 59 Bound systems. 7-8 Brane-scan. 172. 192-193

superthree-brane. 189 Bremsstrahlung. QCD. 46 Bronshtein. theory of the world as

a whole. 21

Ca1ibi-Yau approach. Lagrangians. 204

Calibi-Yau compactifications. 67 deformations. 164 Euler characteristic. 85 N-Z field theories. 131. 133 smooth. massive states. 154 string theory. 162 vortex formation. 162-163

Calibi-Yau threefold. 146. 150 CDF see Fermilab collider Cherenkov detector. 279 Chern-Simons multiplet. 155 Chern-Simons terms. Yang-Mills

action. 184-185 Chlorine experiment

capture rate. 280-281. 282 results. 294

Clebsch-Gordon coefficients. Yukawa couplings. 164

CLEO experiment. 336. 339 Closed universe. expansion. 8. 15 Compton cross section and

kinematics. Standard Model. 305-307

Compton length. 17 Conformal and modular invariance.

string theory. 66 Constant magnetic field. spin

precession. 293-289

415

Coupling theories see Weak interactions

CP violation. 249 B sector. 347

Crab crossings. 369. 382 Cryptons

dark matter. 88 masses. 86

Cube of theories. 21-22

Dark matter. cryptons. 88 Decoup1ing theorem. 242 Dedekind function. 74. 143. 144 Deformation of complex structure.

and target-space duality symmetry. superstring vacua. 137-145

Di1aton vacuum expectation value. 198

Dirac equation Euclidean space. 97. 98 unitary transformation. 13

Dirac magnetic moment. 280. 281 Dirac neutrinos. 269-270. 272 Dirac quantization rule. 170. 174.

186 Distorted Gaussian. 32. 33 DO central tracking chamber.

345-346 Double logarithmic approximation.

28-29 Duff-Lu string. 181 Durham algorithm. jet cross

sections. 25-26

E. mass of a system of free particles. 6-7

Effective form factors. jet cross sections. 29-30

Effective string unification scale. Standard Model. 73-76

Eigenvalue spectrum problem. 97-98 Electrons. and pions. 392 E1ectroweak theory

computations. 111 damping mechanisms. 114-131 LEP tests. 245 mt effects. 242-243 precision tests. 211-221 and unitarity. 119 0-Vacuum. 94-104 weak interactions (coupling

theories). 89. 97-99. 102 see also Precision e1ectroweak

data E10isatron hadron supercollider.

367-379 catastrophic beam loss. 380. 385 discussion. 380-385 luminosity

416

beam dynamics. 371 design strategies. 367-379 goals. 369-370 parameter sets. 374. 375 top luminosity (ultimate ELN).

377 trends. 347

magnet quenches. 385 particles. transverse momenta.

381 ultimate ELN

characteristics. 377-378 maximum attainable. 381

Energy binding. 7-8 definitions. 6-7

Energy-momentum tensor. 4 Epsilons

defined. 229 Standard Model. 235

Equivalence principle. 12 Euclidean action. 98 Euclidean space

Dirac equation. 97. 98 A,04 • 105-106

Euler density. 6-D. 198 Euler number. Betti numbers. 197 Expressions of Interest (EOI). SSC

project. 357

Fayet-I1iopu10s term. 73 Fermi scale. 9 Fermi1ab co11ider

detection strategies. 323-329 discussion. 344-349 experimental results. 329

BB mixing. 336-339 massive gauge bosons. 332-333 production cross sections.

332. 333-336 search for top quark. 339-340 W boson mass. 330-331

goals. 323 luminosity goals. 342-343

prospects. 340-342 Fermions

charge. Standard Model. 97 supersymmetric. D 66 unitary transformation. 13 violation. 90 Yukawa coupling. 86

Five-branes discussion. 192-207 elementary. 176-178 heterotic. 193. 203. 204 outstanding problems. 196 perturbation. 184 quantization. 192 solitonic. 178-181 and string mass spectra. 200 string/five-brane duality. 182-

185 F1avour(s).49

heavy. LEP. 235-238 quark-lepton universality. 228-

229. 230. 234 Fourier transform

classical field. 91 Higgs mass. 101. 102 KRT formula. 109 W field. 102

Frenke1-Kac mechanism. 202 Ga1i1eo Ga1i1ei. historical notes.

4-6. 24

Gallium experiment. expected result. 298

Gauge couplings constants. 9. 11 heterotic string

compactification. 151 higher loop corrections. 154-156

Gauge invariance first coined. 19 standard model. 19

Gaugino. mass term. 205 Gauss-Bonnet term. gravity. 162 Gaussian. distorted. 32. 33 Gaussian spectrum. 33 GEM detector. 355. 359 Generating functionals (GF). 27-28 Germanium crystal detector. 265 Gluons

compared with photons. 19 emission. radiative. 321 form factor. 28 jet. DL Master Equation. 28 massless. 18 radiation. 48 relic. gluonic strings. 17 scattering. 46

Goldstone boson. 273 Goldstone-Hoppe result. 200 Grand Universal Theory (GUT)

flipped supersymmetric SU(5) GUT [4] . 68-70

models. 68-72 one-loop and two-loop levels. 58 simplest model. 50-51 SU(3) x SU(2) x U(l). 67-70 and supersymmetric GUTs. Standard

Model. 50-53 testing models. 51-53 see also Standard Model:

Supersymmetry Gravitational field. space-time. 24 Gravitational properties of

particles. 3-4. 12 Gravitino. mass term. 205 Graviton. massive. 14 Green-Schwarz mechanism. 153. 155.

156 anomaly-cancellation term. 184 superstring p-1. 192

Green's functions. 91. 94. 96 Minkowski space. 99 point-like amplitudes. 101 standard e1ectroweak theory. 99

Hadron colliders see E10isatron hadron supercollider

Hadrons charged. 37 hadronization models. 246-247 light (pions). 36 LPHD hypothesis. 34. 42 mass. 8. 38 massive

MLLAs. 38 truncated QCD cascades. 31

technihadrons. 10 Higgs boson. 10-11

CP-even. CP-odd. 82 gamma collisions. 310 gamma production mechanism. 321 heavy. 218 intermediate mass. search. 313-

318. 322 light. 218 mass. 54. 210

discussion. 344 effective potential formalism.

83 Fourier transform. 101. 102 light compared with heavy. 60 radiative corrections. 80-81

mixing parameters. supersymmetric GUT. 62

neutral. 309-310 particle. Kobayashi-Maskawa

mixing angles. 54 photon-photon collider. 303-319

discussion. 321-322 production in SSC project. 354 Standard Model. 210. 303-319 in supersymmetric models.

Standard Model. 47 symmetry breaking. 354

Higgs Breit-Wigner. 310 Higgs doublets. 70 Higgs fields. 68

black p-branes. 203 residue. 101 term Xmnp. 174

Higgs scalars. 10-11 Higgs sector. exotic nondoublet.

248 Higgs vacuum. 55 Hodge dual operation. 173 Hubble constant. 8 Hubble expansion. 8

IBEe spectrum. 266-267 Inertia. and momentum. 3 Instanton-antiinstanton pairs. 117 Instantons

high energy. 126 semiclassical. 115 solution. 179 strong. 124 Yang-Mills equations of motion.

98

Jacobian factor. 100 JADE algorithm. 25. 26. 42 Jauch plot. 265 Jet cross sections

calculation. 28 Durham algorithm. 25-26 effective form factors. 29-30 JADE algorithm. 25. 26. 42

Jet rates double logarithmic approximation.

28-29 generating functionals. 27-28

Jet-jet invariant mass resolution. 312

Jets. neural networks. 48

417

Kahler class deformations. 132. 135 Kahler manifolds. 133. 134 Kahler potential

equation. 145 modified S-Kahler. 156 scalar fields. 164

Kaluza-Klein analysis. 136 Kaon spectra. 31 Khoze-Ringwald calculation. 128 Klein-Fock-Gordon equation. 19 Klein-Gordon operators. 110 Kobayashi-Maskawa matrix. 249 Kobayashi-Maskawa mixing angles.

Higgs particle. 54 Kosterlitz-Thouless transition. 162 KRT formula

functional integral. 126 valley approach. 108-114

Kurie plot. beta decay. 252-254. 257. 269. 277

Lagrangians Calibi-Yau approach. 204 low energy effective. 195-196 one-loop. 204

AI1l4 amplitudes. 107. 108. 114

approximation. 107 Borel summability. 90. 114. 129 compared with electroweak theory.

105 Euclidean space. 105-106 high order estimates. 90. 120 N-loop amplitude. 127 tree graph amplitudes. 105

Landau poles. 244 Laser photons. Compton

backscattering. 304-307 Lattice gauge theory. 127 Lead. in calorimeter construction.

325 LEP

heavy flavours. 235-238 mZ results. 209-214

Leptonic decay. 324 Leptons. mass. 9 Letters of Intent. SSC project. 358 Lightcone formulation. 206 Lightcone gauge. 193. 194. 200 Liouville model. 85. 87 Lipatov. large order perturbation

theory. 104-108 Lorentz invariance. 192 Lorentz scalar. 17 LPHD hypothesis. 34. 42 Luminosity distribution. Standard

Model. 307-309 Lund strings. 46

Magnetic field. sun. 290-291 Majorana neutrinos. 269-270. 272 'Majoron'. 273 Mass

discussion. 12-24 and energy. 7 Majorana. 10 nature of

418

and scalars. 10-11 XVI-XVII centuries. 4-6 XVIII-XIX centuries. 6

negative. 13 Newton's definition. 5 of a particle. defined. 2 patterns. elementary particles.

9-10 relativistic. 2 system of free particles. 6-7

Mass-shell definition. 59. 61 Maxwell equations. 6

in D-4. 173 Mellin transformed spectrum. 32 Meson decays. B mesons. 362 Minkowski space

asymptotic. 15 external. 16. 24 Green's functions. 99

MLLA effects defined. 34 parton cascades. 34-38

MLLA equations. 27 MLLA evolution equations. 32 MLLA form factors. 27 Momentum. time derivative. 2 Monopoles. elementary. solitonic.

174-175 MSW solution. Weinberg-Salam mode.

281. 284 Multidrift tube detector. 389-390 Muon-electron. 346 Muons

dimuon system. 327. 328 spectra. 338

Nambu-Goto action. 201 Neural networks. jets. 48 Neutrino: antineutrino scattering.

229 Neutrino physics. 251-273

17 keV neutrino. 254-262 recent experiments. 262-268

Big Bang nucleosynthesis. 270-271 discussion. 268-269. 275-278 kinematics of beta decay. 251-254 supernova neutrinos. 271-273

Neutrino-nucleus deep inelastic scattering. 230

Neutrinos activation. B + L violations. 125 beryllium. 295. 302 gallium. 298 heavy. 237 mass. 10 solar. wave length. 14 solar neutrino problem. 279

case of varying magnetic field. 290-291

discussion. 301-302 expected Gallium result. 298 fitting the data. 294-297 four by four case. 292-294 Kamiokande signal. 279. 282.

301 SAGE experiment. 298

Neutrinos (cont.) solar neutrino problem (cont.)

spin precession in constant magnetic field. 283-289

standard solar model (SSM). 279

time-varying. 279 supernovae. 302

Newton. historical notes. 5 Newtonian constant. 8 Newtonian potential. 4 Nitrogen neutrinos. 295 Noether charge. string. 178. 180 Non-Abelian gauge theories. 94 NSNP see Neutrinos. solar neutrino

problem. time varying Nucleons. antinucleons. 271

p-branes. 170 black. 202 super. 202

Parasitic crossings. 369. 382 Particle. free. energy. defined. 13 Partons

cascades MLLA effects. 34-38 predictions. 41. 43

multiplicity. 31 production. 324

Pauli matrix combinations. 99 PDEs. non-linear. 199 PEP/PETRA. 237 Perturbation

QCD. pomeron. 124 radiative corrections. 212 SUSY-breaking. 207

Perturbation theory. 66. 90 Photons

compared with gluons. 19 mass. 9 photon-photon collider. Higgs

boson. 303-319 Picard-Fuchs equations. 131. 133.

145-151 Pions. 36. 41 Planck scale

QFT. 17 superunification. 11

PMP. scintillators. 389 Poincare scalar. 17 Polarizations. measurements. 241-

242 Pomeron. high e scattering. 124 pp collisions. 45-46. 347

B + L violations. 123 Precision electroweak data. 209-238

discussion I and II. 241-250 model independent analysis of

data. 221-235 see also Electroweak theory

Proton colliders. see also Eloisatron hadron supercollider: SSC project

Proton lifetime. non-SUSY. Standard Model. 81

Pseudoparticles. 25

QI1l' 32 Quantum chromodynamics (QCD)

bremsstrahlung. 46 MLLA effects. 34 phenomenology

discussion I. 41-44 discussion II. 45-48 jet rates and truncated parton

cascades. 25-40 sum rules. 8

Quantum mechanics consistency. 193 and relativity. 63-64

Quark-lepton universality. 227-229. 230. 234

Quarks and gluons. confined in hadrons.

8 heavy. 45. 46-47

mass. 47 mass. Fermi scale. 9 top. 9

Fermilab collider program. 323. 339-340

LEP analysis. 242 mass. 18. 209-210

Yukawa coupling. 18

Reissner-Nordstrom limit. 188 black hole solution. 202

Relativity general. 64 and quantum mechanics. 63-64 relativistic particle. weak G

field. 4 special. 64

Riemann tensor. scalar fields. 164 Ringwald-Espinosa formula. 90. 99.

100. 117

s-model sources. Yang-Mills action. 185-188

Saddle points. 103. 104. 107. 112 approximations. 126

SAGE experiment. solar neutrino problem. 298

Sargent rule. 270 Scalar fields. Riemann tensor. 164 Scalars. nature of mass. 10-11 Scintillators. PMP. 389 SOC detector. 354 Semiclassical formula

n-leg amplitude. 109 quantum corrections. 104 representative correction. 109

SLD detector. Fast Monte Carlo Simulation. 312. 314

SNP see Neutrinos. solar neutrino problem

Solar neutrino problem Kamiokande signal. 279. 282. 301 standard solar model (SSM). 279

Solitons five-branes. 198-199 solution. 188

Space-time curved. duality. 162

419

Space-time (cont.) D. 170-173 gravitational field. 24 singularities. 207 string compactification. 162

Sparticle mass. 80 Sphaleron. B + L amplitude. 116-118 Spin precession. constant magnetic

field. 293-289 Spontaneous symmetry breaking

sector see Standard Model SSC Project

chronology. 351 discussion. 361-365 experimental program. 357-360 Expressions of Interest (EOI).

357 fixed-target experiments. 364 Letters of Intent. 358 location. 352 luminosity. upgrades. 361. 364 parameters. 353 physics. 354-357 prospects. 353 ring schematic. 352

Standard electroweak theory. weak interactions (coupling theories). 96

Standard Model Coleman-Weinberg limit. 79 Compton cross section and

kinematics. 305-307 discussion I. 79-83 discussion II. 83-88 effective string unification

scale. 73-76 fermion charge. 97 flipped supersymmetric SU(5)

GUT. 68-70 derived from string [4]. 70-72

gauge invariance. 19 GUTs and supersymmetric GUTs.

50-53 Higgs bosons. 210. 303-319

supersymmetric models. 47 light stop scenario. 81 linear combinations of E1.E2.E3.

222-227 luminosity distribution. 307-309 mass problem. 49. 53-56 model independent analysis of

data. 221-235 non-SUSY. 80

proton lifetime. 81 precision tests. LEP. 209-211 predictions ZSHAPE. 216 problems. 49-50 string model-building. 63-68 superstring 'prediction' for mt.

72-73 supersymmetric SU(5) GUT. 58-63 symmetry breaking. 354 t quark. 53 WW-scattering. 20 Yukawa couplings. 54. 57 see also GUT

420

Stanford Linear Accelerator Center. 312

Stefan's Law. 271 String theory

2-D world sheet. loop expansion. 197

Calibi-Yau. 162 compactification. space-time. 162 conformal and modular invariance.

66 d-2 sigma model. 196 discrete or continuous spectrum.

195 duality symmetry. 202 elementary. 176-178 and fivebranes. 169-189

discussion I. 192-194 discussion II. 204-207

heterotic. left-moving and right-moving sectors. 67

loop diagrams. 166 mass spectra. and five-branes.

200 model-building. Standard Model.

63-68 Noether charge. 178. 180 quantization. 194 scales. 165 solitonic. 178-181. 188 String Unification scale. 88 Theory of Everything. 50. 64-68 see also Superstring theory

String/five-brane duality. 182-185 Sudakov form factor exponent. 29 Sun. magnetic field. 290-291 Supercolliders

acronym defined. 391 calorimeter. 394 data analysis. 391 new detectors. 387

discussion. 388-397 safety. 397 time constraints. 390 see also ELN: SSC project

Superconducting Super Collider see SSC project

Supermembranes. 170 Supernova neutrinos. neutrino

physics. 271-273. 302 Superstring theory

D-10. 87 type IIA and B. 199-200

'prediction' for mt. Standard Model. 72-73

see also String theory Superstring vacua. 131-157

deformation of complex structure and target-space duality symmetry. 137-145

discussion. 162-167 moduli dependence of gauge

couplings. 152-161 Picard-Fuchs equations. 131. 133.

145-151 special geometry. 132-136 target-space duality anomaly

cancellation. 152-161

Supersymmetric GUT breaking

gauge group. 86 scale. 79-83

CDF. mass limits. 344-349 Higgs mixing parameters. 62

Superthree-brane. brane-scan. 189

Target-space duality anomaly cancellation. superstring vacua. 152-161

Technicolour models. 248 Tevatron

B production. 246 layout. 340-343 mt effects. 243

Thallium. Standard Model discrepancy. 81

Theories. cube of. 21-22 Theory of Everything. 17. 21. 22

string theory. 50. 64-68 Thomson limit. 59 It-Hooft tunnelling. 100-101

B + L violation. 120 damping factor. 103 estimate. 117

It-Hooft-Polyakov monopole. 203 Three-branes. 201 TOE see Theory of Everything Toroidal compactifications. moduli

space. 142 Transition magnetic moment. 280 Tritium. decay experiments. 254-257 Truncated QCD cascades. massive

hadrons. 31

Unification. SU(3) x SU(2) x U(l). 49. 50

Unitarity. and electroweak theory. 119

Universe baryon number. 85 closed. 8. 14. 15. 16 massless. 15 total energy. 15

0-Vacuum. electroweak theory. 94-104

Vacuum. energy density. 8 Valley approach. 127

B + L violations. 121 KRT formula. 108-114

Valley method. B + L violations. 128

Velocity. defined. 2. 3 Vortex formation. Calibi-Yau. 162-

163

W bosons detection. 323-331 mass. experimental results.

Fermilab collider. 330-331 W field. 100. 101

bond function. 103 Fourier transform. 102 polarization sum. 102

W mass. Ill. 112

bond function. 117-118 multi-W exchange. 112

Weak interactions (coupling theories). 89-121

B + L current. 97-99 B + L violation. 89. 102 discussion I. 123-125 discussion II. 125-129 phase space growth. 90-94 semiclassical approximations.

90-94 standard electroweak theory. 96

Weil-Petersson metric. 137 Weinberg-Salam mode. MSW solution.

281. 284 Weyl invariance. 201 Winding number solutions. 124 World sheet

bosons and fermions. 203 Euler number. 197

World as a whole. Bronshtein theory. 21

World-line. world-sheet. 64. 65-66 WW

fusion. 303 initial state branching. 116

WW-scattering. 20

Yang-Mills action Chern-Simons terms. 184-185 D-10 supergravity. 179. 180 internal symmetry. 204 quadratic. 169. 183-184. 185. 188 quartic. 169. 183-184. 186-188 s-model sources. 185-188 supersymmetric SU(N) model. 200

Yang-Mills equation of motion instantons. 98 solution. 185. 187

Yang-Mills theory (N-1). 154 Yukawa couplings

a(3) coefficient. 151 automorphic tensor. 164 Clebsch-Gordon coefficients. 164 constant. 72. 73. 80 quark. 18 Standard Model. 54. 57 tensor. Calibi-Yau. 165

Yukawa sector. CP violation. 86

421

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