Hadron energy reconstruction for the ATLAS calorimetry in the framework of the non-parametrical method

6533b820fe1ef96bd127a657

RESEARCH PRODUCT

Hadron energy reconstruction for the ATLAS calorimetry in the framework of the non-parametrical method

S. Akhmadaliev P. Amaral G. Ambrosini A. Amorim K. Anderson M.l. Andrieux B. Aubert E. Auge F. Badaud L. Baisin F. Barreiro G. Battistoni A. Bazan K. Bazizi A. Belymam D. Benchekroun S. Berglund J.c. Berset G. Blanchot A. Bogush C. Bohm V. Boldea W. Bonivento M. Bosman N. Bouhemaid D. Breton P. Brette C. Bromberg J. Budagov S. Burdin L. Caloba F. Camarena D.v. Camin B. Canton M. Caprini J. Carvalho P. Casado M.v. Castillo D. Cavalli M. Cavalli-sforza V. Cavasinni R. Chadelas M. Chalifour L. Chekhtman J.l. Chevalley I. Chirikov-zorin G. Chlachidze M. Citterio W.e. Cleland C. Clement M. Cobal F. Cogswell J. Colas J. Collot S. Cologna S. Constantinescu G. Costa D. Costanzo M. Crouau F. Daudon J. David M. David T. Davidek J. Dawson K. De C. De La Taille J. Del Peso T. Del Prete P. De Saintignon B. Di Girolamo B. Dinkespiller S. Dita J. Dodd J. Dolejsi Z. Dolezal R. Downing J.j. Dugne Daniel Dzahini I. Efthymiopoulos D. Errede S. Errede H. Evans G. Eynard F. Fassi P. Fassnacht Anthony Ferrari A. Ferrer V. Flaminio D. Fournier G. Fumagalli E. Gallas M. Gaspar V. Giakoumopoulou F. Gianotti O. Gildemeister N. Giokaris V. Glagolev V. Glebov A. Gomes V. Gonzalez S. Gonzalez De La Hoz V. Grabsky E. Grauges P. Grenier H. Hakopian M. Haney C. Hebrard A. Henriques L. Hervas E. Higon S. Holmgren J.y. Hostachy A. Hoummada J. Huston D. Imbault Yu. Ivanyushenkov P. Jenny S. Jezequel E. Johansson K. Jon-and R. Jones A. Juste S. Kakurin A. Karyukhin Yu. Khokhlov J. Khubua V. Klyukhin G. Kolachev S. Kopikov M. Kostrikov V. Kozlov P. Krivkova V. Kukhtin M. Kulagin Y. Kulchitsky M. Kuzmin L. Labarga G. Laborie D. Lacour B. Laforge S. Lami V. Lapin O. Le Dortz M. Lefebvre T. Le Flour R. Leitner M. Leltchouk J. Li M. Liablin O. Linossier D. Lissauer F. Lobkowicz M. Lokajicek Yu. Lomakin J.m. Lopez Amengual B. Lund-jensen A. Maio D. Makowiecki S. Malyukov L. Mandelli B. Mansoulie L. Mapelli C.p. Marin P. Marrocchesi F. Marroquin P. Martin A. Maslennikov N. Massol L. Mataix M. Mazzanti E. Mazzoni F. Merritt B. Michel R. Miller I. Minashvili L. Miralles E. Mnatsakanian E. Monnier Gerard Montarou G. Mornacchi M. Moynot G.-s. Muanza P. Nayman S. Nemecek M. Nessi S. Nicoleau M. Niculescu J.m. Noppe A. Onofre D. Pallin D. Pantea R. Paoletti I.c. Park G. Parrour J. Parsons A. Pereira L. Perini J.a. Perlas P. Perrodo J. Pilcher J. Pinhao H. Plothow-besch L. Poggioli S. Poirot L. Price Y. Protopopov J. Proudfoot P. Puzo V. Radeka D. Rahm G. Reinmuth G. Renzoni S. Rescia S. Resconi R. Richards J.p. Richer I. Riu C. Roda S. Rodier J. Roldan J.b. Romance V. Romanov P. Romero F. Rossel N. Russakovich P. Sala E. Sanchis H. Sanders C. Santoni J. Santos D. Sauvage G. Sauvage L. Sawyer L. P. Says A.c. Schaffer P. Schwemling J. Schwindling N. Seguin-moreau W. Seidl J.m. Seixas B. Sellden M. Seman A. Semenov L. Serin E. Shaldaev M. Shochet V. Sidorov J. Silva V. Simaitis S. Simion A. Sissakian R. Snopkov J. Soderqvist A. Solodkov A. Soloviev I. Soloviev P. Sonderegger K. Soustruznik F. Spano R. Spiwoks R. Stanek E. Starchenko P. Stavina R. Stephens M. Suk A. Surkov I. Sykora H. Takai F. Tang S. Tardell F. Tartarelli P. Tas J. Teiger F. Teubert J. Thaler J. Thion Y. Tikhonov S. Tisserant S. Tokar N. Topilin Z. Trka M. Turcotte S. Valkar M.j. Varanda A. Vartapetian F. Vazeille I. Vichou V. Vinogradov S. Vorozhtsov V. Vuillemin A. White M. Wielers I. Wingerter-seez H. Wolters N. Yamdagni C. Yosef A. Zaitsev R. Zitoun Y. Zolnierowski

subject

Nuclear and High Energy Physics Particle physics Physics::Instrumentation and Detectors Hadron FOS: Physical sciences chemistry.chemical_element Calorimetry Electron Calorimetry 01 natural sciences Partícules (Física nuclear)High Energy Physics - Experiment Energy measurement Nuclear physics High Energy Physics - Experiment (hep-ex)Pion Shower counter 0103 physical sciences [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex]Computer data analysis [PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det]Combined calorimeter Detectors and Experimental Techniques 010306 general physics Nuclear Experiment Instrumentation Physics Large Hadron Collider Argon 010308 nuclear & particles physics SHOWER DEVELOPMENT; RESOLUTION SHOWER DEVELOPMENT Calorimeter RESOLUTION chemistry Scintillation counter High Energy Physics::Experiment Compensation

description

This paper discusses hadron energy reconstruction for the ATLAS barrel prototype combined calorimeter (consisting of a lead-liquid argon electromagnetic part and an iron-scintillator hadronic part) in the framework of the non-parametrical method. The non-parametrical method utilizes only the known $e/h$ ratios and the electron calibration constants and does not require the determination of any parameters by a minimization technique. Thus, this technique lends itself to an easy use in a first level trigger. The reconstructed mean values of the hadron energies are within $\pm 1%$ of the true values and the fractional energy resolution is $[(58\pm3)% /\sqrt{E}+(2.5\pm0.3)%]\oplus (1.7\pm0.2)/E$. The value of the $e/h$ ratio obtained for the electromagnetic compartment of the combined calorimeter is $1.74\pm0.04$ and agrees with the prediction that $e/h > 1.7$ for this electromagnetic calorimeter. Results of a study of the longitudinal hadronic shower development are also presented. The data have been taken in the H8 beam line of the CERN SPS using pions of energies from 10 to 300 GeV.

year	journal	country	edition	language
2002-01-01

10.1016/s0168-9002(01)01229-3 https://doi.org/10.1016/s0168-9002(01)01229-3