The SeaQuest spectrometer at Fermilab

C. Aidala,John. Arrington,C. Ayuso,B M Bowen,M. L. Bowen,K.L. Bowling,Andy W. Brown,C. N. Brown,R Byrd,R.E. Carlisle,Tianbao Chang,Wen Chen Chang,A. Chen,J-Y Chen,D.C. Christian,X. Chu,B.P. Dannowitz,M. S. Daugherity,M. Diefenthaler,J. Dove,C. Durandet,L. El-Fassi,E. Erdös,D.M. Fox,D.F. Geesaman,R. Gilman,Y. Goto,L. Guo,R.-S. Guo,T. Hague,C. R. Hicks,R.J. Holt,D. Isenhower,X. Jiang,Joseph M. Katich,B. M. Kerns,E.R. Kinney,N.D. Kitts,Andi Klein,D. Kleinjan,J. Kraś,Y. Kudo,P. j. Lin,D. W. Liu,K. Liu,M. X. Liu,Wolfgang Lorenzon,N. Makins,J. D. Martinez,Randall Evan McClellan,B. McDonald,P. L. McGaughey,S.E. McNease,M. M. Medeiros,B. Miller,A J Miller,S. Miyasaka,Y. Miyachi,I.A. Mooney,D. H. Morton,B. Nadim,K. Nagai,K. Nakahara,K. Nakano,S Nara,S. Obata,Jen-Chieh Peng,S. Prasad,A. J. R. Puckett,B. J. Ramson,R.S. Raymond,P. E. Reimer,J. G. Rubin,R. Salinas,F. Sanftl,S. Sawada,T. Sawada,M.B.C. Scott,L.E. Selensky,T. A. Shibata,S Shiu,D.-S. Su,A S Tadepalli,M. Teo,B.G. Tice,C. L. Towell,R. S. Towell,Sho Uemura,S. G. Wang,S. Watson,N. White,A.B. Wickes,M. R. Wood,J. Wu,Z Xi,Z. Ye,Y Yin

The SeaQuest spectrometer at Fermilab

2019

C. Aidala
John. Arrington
C. Ayuso
B M Bowen
M. L. Bowen
K.L. Bowling
Andy W. Brown
C. N. Brown
R Byrd
R.E. Carlisle
Tianbao Chang
Wen Chen Chang
A. Chen
J-Y Chen
D.C. Christian
X. Chu
B.P. Dannowitz
M. S. Daugherity
M. Diefenthaler
J. Dove
C. Durandet
L. El-Fassi
E. Erdös
D.M. Fox
D.F. Geesaman
R. Gilman
Y. Goto
L. Guo
R.-S. Guo
T. Hague
C. R. Hicks
R.J. Holt
D. Isenhower
X. Jiang
Joseph M. Katich
B. M. Kerns
E.R. Kinney
N.D. Kitts
Andi Klein
D. Kleinjan
J. Kraś
Y. Kudo
P. j. Lin
D. W. Liu
K. Liu
M. X. Liu
Wolfgang Lorenzon
N. Makins
J. D. Martinez
Randall Evan McClellan
B. McDonald
P. L. McGaughey
S.E. McNease
M. M. Medeiros
B. Miller
A J Miller
S. Miyasaka
Y. Miyachi
I.A. Mooney
D. H. Morton
B. Nadim
K. Nagai
K. Nakahara
K. Nakano
S Nara
S. Obata
Jen-Chieh Peng
S. Prasad
A. J. R. Puckett
B. J. Ramson
R.S. Raymond
P. E. Reimer
J. G. Rubin
R. Salinas
F. Sanftl
S. Sawada
T. Sawada
M.B.C. Scott
L.E. Selensky
T. A. Shibata
S Shiu
D.-S. Su
A S Tadepalli
M. Teo
B.G. Tice
C. L. Towell
R. S. Towell
Sho Uemura
S. G. Wang
S. Watson
N. White
A.B. Wickes
M. R. Wood
J. Wu
Z Xi
Z. Ye
Y Yin

Abstract The SeaQuest spectrometer at Fermilab was designed to detect oppositely-charged pairs of muons (dimuons) produced by interactions between a 120 GeV proton beam and liquid hydrogen, liquid deuterium and solid nuclear targets. The primary physics program uses the Drell–Yan process to probe antiquark distributions in the target nucleon. The spectrometer consists of a target system, two dipole magnets and four detector stations. The upstream magnet is a closed-aperture solid iron magnet which also serves as the beam dump, while the second magnet is an open aperture magnet. Each of the detector stations consists of scintillator hodoscopes and a high-resolution tracking device. The FPGA-based trigger compares the hodoscope signals to a set of pre-programmed roads to determine if the event contains oppositely-signed, high-mass muon pairs.

Keywords:

Magnet
Particle physics
Fermilab
Physics
Hodoscope
Muon
Detector
Deuterium
Nuclear magnetic resonance
Beam dump
Spectrometer
Nuclear physics
Optics
Scintillator

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