CINECA IRIS Institutional Research Information System

The main characteristics of the COMPASS experimental setup for physics with hadron beams are described. This setup was designed to perform exclusive measurements of processes with several charged and/or neutral particles in the final state. Making use of a large part of the apparatus that was previously built for spin structure studies with a muon beam, it also features a new target system as well as new or upgraded detectors. The hadron setup is able to operate at the high incident hadron flux available at CERN. It is characterised by large angular and momentum coverages, large and nearly flat acceptances, and good two and three-particle mass resolutions. In 2008 and 2009 it was successfully used with positive and negative hadron beams and with liquid hydrogen and solid nuclear targets. This paper describes the new and upgraded detectors and auxiliary equipment, outlines the reconstruction procedures used, and summarises the general performance of the setup.

The COMPASS setup for physics with hadron beams

ALEXEEV, Maxim;AMOROSO, Antonio;BALESTRA, Ferruccio;CHIOSSO, Michela;GNESI, IVAN;GRASSO, Antonino;PARSAMYAN, BAKUR;
2015-01-01

Abstract

The main characteristics of the COMPASS experimental setup for physics with hadron beams are described. This setup was designed to perform exclusive measurements of processes with several charged and/or neutral particles in the final state. Making use of a large part of the apparatus that was previously built for spin structure studies with a muon beam, it also features a new target system as well as new or upgraded detectors. The hadron setup is able to operate at the high incident hadron flux available at CERN. It is characterised by large angular and momentum coverages, large and nearly flat acceptances, and good two and three-particle mass resolutions. In 2008 and 2009 it was successfully used with positive and negative hadron beams and with liquid hydrogen and solid nuclear targets. This paper describes the new and upgraded detectors and auxiliary equipment, outlines the reconstruction procedures used, and summarises the general performance of the setup.
2015
779
69
115
P. Abbon;C. Adolph;R. Akhunzyanov;Yu. Alexandrov;M.G. Alexeev;G.D. Alexeev;A. Amoroso;V. Andrieux;V. Anosov;A. Austregesilo;B. Badełek;F. Balestra;J. Barth;G. Baum;R. Beck;Y. Bedfer;A. Berlin;J. Bernhard;K. Bicker;E.R. Bielert;J. Bieling;R. Birsa;J. Bisplinghoff;M. Bodlak;M. Boer;P. Bordalo;F. Bradamante;C. Braun;A. Bressan;M. Büchele;E. Burtin;L. Capozza;P. Ciliberti;M. Chiosso;S.U. Chung;A. Cicuttin;M. Colantoni;D. Cotte;M.L. Crespo;Q. Curiel;T. Dafni;S. Dalla Torre;S.S. Dasgupta;S. Dasgupta;O.Yu. Denisov;D. Desforge;A.M. Dinkelbach;S.V. Donskov;N. Doshita;V. Duic;W. Dünnweber;D. Durand;M. Dziewiecki;A. Efremov;C. Elia;P.D. Eversheim;W. Eyrich;M. Faessler;A. Ferrero;M. Finger;M. Finger;H. Fischer;C. Franco;N. du Fresne von Hohenesche;J.M. Friedrich;V. Frolov;L. Gatignon;F. Gautheron;O.P. Gavrichtchouk;S. Gerassimov;R. Geyer;A. Giganon;I. Gnesi;B. Gobbo;S. Goertz;M. Gorzellik;S. Grabmüller;A. Grasso;M. Gregori;B. Grube;T. Grussenmeyer;A. Guskov;F. Haas;D. von Harrach;D. Hahne;R. Hashimoto;F.H. Heinsius;F. Herrmann;F. Hinterberger;Ch. Höppner;N. Horikawa;N. d׳Hose;S. Huber;S. Ishimoto;A. Ivanov;Yu. Ivanshin;T. Iwata;R. Jahn;V. Jary;P. Jasinski;P. Jörg;R. Joosten;E. Kabuß;B. Ketzer;G.V. Khaustov;Yu.A. Khokhlov;Yu. Kisselev;F. Klein;K. Klimaszewski;J.H. Koivuniemi;V.N. Kolosov;K. Kondo;K. Königsmann;I. Konorov;V.F. Konstantinov;A.M. Kotzinian;O. Kouznetsov;M. Krämer;Z.V. Kroumchtein;N. Kuchinski;R. Kuhn;F. Kunne;K. Kurek;R.P. Kurjata;A.A. Lednev;A. Lehmann;M. Levillain;S. Levorato;J. Lichtenstadt;A. Maggiora;A. Magnon;N. Makke;G.K. Mallot;C. Marchand;J. Marroncle;A. Martin;J. Marzec;J. Matousek;H. Matsuda;T. Matsuda;G. Menon;G. Meshcheryakov;W. Meyer;T. Michigami;Yu.V. Mikhailov;Y. Miyachi;M.A. Moinester;A. Nagaytsev;T. Nagel;F. Nerling;S. Neubert;D. Neyret;V.I. Nikolaenko;J. Novy;W.-D. Nowak;A.S. Nunes;A.G. Olshevsky;I. Orlov;M. Ostrick;R. Panknin;D. Panzieri;B. Parsamyan;S. Paul;G. Pesaro;V. Pesaro;D.V. Peshekhonov;C. Pires;S. Platchkov;J. Pochodzalla;V.A. Polyakov;J. Pretz;M. Quaresma;C. Quintans;S. Ramos;C. Regali;G. Reicherz;J-M. Reymond;E. Rocco;N.S. Rossiyskaya;J.-Y. Rousse;D.I. Ryabchikov;A. Rychter;A. Samartsev;V.D. Samoylenko;A. Sandacz;S. Sarkar;I.A. Savin;G. Sbrizzai;P. Schiavon;C. Schill;T. Schlüter;K. Schmidt;H. Schmieden;K. Schönning;S. Schopferer;M. Schott;O.Yu. Shevchenko;L. Silva;L. Sinha;S. Sirtl;M. Slunecka;S. Sosio;F. Sozzi;A. Srnka;L. Steiger;M. Stolarski;M. Sulc;R. Sulej;H. Suzuki;A. Szabelski;T. Szameitat;P. Sznajder;S. Takekawa;G. Terça;J. ter Wolbeek;S. Tessaro;F. Tessarotto;F. Thibaud;V. Tskhay;S. Uhl;I. Uman;M. Virius;L. Wang;T. Weisrock;Q. Weitzel;M. Wilfert;R. Windmolders;H. Wollny;K. Zaremba;M. Zavertyaev;E. Zemlyanichkina;M. Ziembicki;A. Zink
03A-Articolo su Rivista
File in questo prodotto:
File Dimensione Formato  
1-s2.0-S0168900215000662-main_compressed.pdf

Accesso riservato

Tipo di file: PDF EDITORIALE
Dimensione 2.53 MB
Formato Adobe PDF
  Visualizza/Apri   Richiedi una copia
2.53 MB Adobe PDF   Visualizza/Apri   Richiedi una copia

I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.

Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/2318/158069
Citazioni
  • ???jsp.display-item.citation.pmc??? ND
  • Scopus 67
  • ???jsp.display-item.citation.isi??? 56
social impact