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The HERMES spectrometer

Authors :
K. Ackerstaff
A. Airapetian
N. Akopov
M. Amarian
V. Andreev
E.C. Aschenauer
R. Avakian
H. Avakian
A. Avetissian
B. Bains
S. Barrow
W. Beckhusen
M. Beckmann
St. Belostotski
E. Belz
Th. Benisch
S. Bernreuther
N. Bianchi
J. Blouw
H. Böttcher
A. Borissov
J. Brack
B. Braun
B. Bray
S. Brons
W. Brückner
A. Brüll
H.J. Bulten
G.P. Capitani
P. Carter
P. Chumney
E. Cisbani
S. Clark
S. Colilli
H. Coombes
G.R. Court
P. Delheij
E. Devitsin
C.W. de Jager
E. De Sanctis
D. De Schepper
P.K.A. de Witt Huberts
P. Di Nezza
M. Doets
M. Düren
A. Dvoredsky
G. Elbakian
J. Emerson
A. Fantoni
A. Fechtchenko
M. Ferstl
D. Fick
K. Fiedler
B.W. Filippone
H. Fischer
H.T. Fortune
J. Franz
S. Frullani
M.-A. Funk
N.D. Gagunashvili
P. Galumian
H. Gao
Y. Gärber
F. Garibaldi
G. Gavrilov
P. Geiger
V. Gharibyan
V. Giordjian
F. Giuliani
A. Golendoukhin
B. Grabowski
G. Graw
O. Grebeniouk
P. Green
G. Greeniaus
M. Gricia
C. Grosshauser
A. Gute
J.P. Haas
K. Hakelberg
W. Haeberli
J.-O. Hansen
D. Hasch
O. Hausser
R. Henderson
Th. Henkes
R. Hertenberger
Y. Holler
R.J. Holt
H. Ihssen
A. Izotov
M. Iodice
H.E. Jackson
A. Jgoun
C. Jones
R. Kaiser
J. Kelsey
E. Kinney
M. Kirsch
A. Kisselev
P. Kitching
H. Kobayashi
E. Kok
K. Königsmann
M. Kolstein
H. Kolster
W. Korsch
S. Kozlov
V. Kozlov
R. Kowalczyk
L. Kramer
B. Krause
A. Krivchitch
V.G. Krivokhijine
M. Kueckes
P. Kutt
G. Kyle
W. Lachnit
R. Langstaff
W. Lorenzon
M. Lucentini
A. Lung
N. Makins
V. Maleev
S.I. Manaenkov
K. Martens
A. Mateos
K. McIlhany
R.D. McKeown
F. Meißner
F. Menden
D. Mercer
A. Metz
N. Meyners
O. Mikloukho
C.A. Miller
M.A. Miller
R. Milner
V. Mitsyn
G. Modrak
J. Morton
A. Most
R. Mozzetti
V. Muccifora
A. Nagaitsev
Y. Naryshkin
A.M. Nathan
F. Neunreither
M. Niczyporuk
W.-D. Nowak
M. Nupieri
P. Oelwein
H. Ogami
T.G. O’Neill
R. Openshaw
V. Papavassiliou
S.F. Pate
S. Patrichev
M. Pitt
H.J. Plett
H.R. Poolman
S. Potashov
D. Potterveld
B. Povh
V. Prahl
G. Rakness
V. Razmyslovich
R. Redwine
A.R. Reolon
R. Ristinen
K. Rith
H.O. Roloff
G. Röper
P. Rossi
S. Rudnitsky
H. Russo
D. Ryckbosch
Y. Sakemi
F. Santavenere
I. Savin
F. Schmidt
H. Schmitt
G. Schnell
K.P. Schüler
A. Schwind
T.-A. Shibata
T. Shin
B. Siebels
A. Simon
K. Sinram
W.R. Smythe
J. Sowinski
M. Spengos
K. Sperber
E. Steffens
J. Stenger
J. Stewart
F. Stock
U. Stößlein
M. Sutter
H. Tallini
S. Taroian
A. Terkulov
D. Thiessen
B. Tipton
V. Trofimov
A. Trudel
M. Tytgat
G.M. Urciuoli
R. Van de Vyver
J.F.J. van den Brand
G. van der Steenhoven
J.J. van Hunen
D. van Westrum
A. Vassiliev
M.C. Vetterli
M.G. Vincter
E. Volk
W. Wander
T.P. Welch
S.E. Williamson
T. Wise
G. Wöbke
K. Woller
S. Yoneyama
K. Zapfe-Düren
T. Zeuli
H. Zohrabian
(Astro)-Particles Physics
Source :
Nuclear Instruments & Methods in Physics Research Section A-Accelerators Spectrometers Detectors and Associated Equipment, 417(2-3), 230-265. Elsevier, Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors, and Associated Equipment, 417, 230-265. Elsevier, Ackerstaff, K, Blouw, J, Bulten, H J, Kolstein, M, Poolman, H R & van den Brand, J F J 1998, ' The HERMES spectrometer. ', Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors, and Associated Equipment, vol. 417, pp. 230-265 . https://doi.org/10.1016/S0168-9002(98)00769-4
Publication Year :
1998

Abstract

The HERMES experiment is collecting data on inclusive and semi-inclusive deep inelastic scattering of polarised positrons from polarised targets of H, D, and He. These data give information on the spin structure of the nucleon. This paper describes the forward angle spectrometer built for this purpose. The spectrometer includes numerous tracking chambers (micro-strip gas chambers, drift and proportional chambers) in front of and behind a 1.3 T.m magnetic field, as well as an extensive set of detectors for particle identification (a lead-glass calorimeter, a pre-shower detector, a transition radiation detector, and a threshold Cherenkov detector). Two of the main features of the spectrometer are its good acceptance and identification of both positrons and hadrons, in particular pions. These characteristics, together with the purity of the targets, are allowing HERMES to make unique contributions to the understanding of how the spins of the quarks contribute to the spin of the nucleon.<br />37 pages, 32 figures, 4 tables

Subjects

Subjects :
HERMES experiment
Nuclear and High Energy Physics
Particle physics
semi-inclusive scattering
(e
Physics::Instrumentation and Detectors
Cherenkov detector
CALORIMETERS
FOS: Physical sciences
deep inelastic lepton scattering
(e,e''h)
Tracking (particle physics)
Particle identification
High Energy Physics - Experiment
INORGANIC MATERIALS
law.invention
High Energy Physics - Experiment (hep-ex)
e''h)
GAS-MIXTURES
law
Nuclear Experiment
Instrumentation
Physics
Calorimeter (particle physics)
Spectrometer
PERFORMANCE
magnetic spectrometer
Deep inelastic scattering
Transition radiation detector
CHAMBERS
High Energy Physics::Experiment

Details

Language :
English
ISSN :
01689002
Volume :
417
Database :
OpenAIRE
Journal :
Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors, and Associated Equipment
Accession number :
edsair.doi.dedup.....cf3e667456b0fdbc424616e3a8e588dd

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