Precise Measurement of the Top-Quark Mass from lepton plus jets Events

Precise Measurement of the Top-Quark Mass from lepton þ jets Events

V. M. Abazov,36B. Abbott,75M. Abolins,65B. S. Acharya,29M. Adams,51T. Adams,49E. Aguilo,6M. Ahsan,59 G. D. Alexeev,36G. Alkhazov,40A. Alton,64,*G. Alverson,63G. A. Alves,2M. Anastasoaie,35L. S. Ancu,35T. Andeen,53

B. Andrieu,17M. S. Anzelc,53M. Aoki,50Y. Arnoud,14M. Arov,60M. Arthaud,18A. Askew,49B. A˚ sman,41 A. C. S. Assis Jesus,3O. Atramentov,49C. Avila,8F. Badaud,13L. Bagby,50B. Baldin,50D. V. Bandurin,59P. Banerjee,29

S. Banerjee,29E. Barberis,63A.-F. Barfuss,15P. Bargassa,80P. Baringer,58J. Barreto,2J. F. Bartlett,50U. Bassler,18 D. Bauer,43S. Beale,6A. Bean,58M. Begalli,3M. Begel,73C. Belanger-Champagne,41L. Bellantoni,50A. Bellavance,50

J. A. Benitez,65S. B. Beri,27G. Bernardi,17R. Bernhard,23I. Bertram,42M. Besanc¸on,18R. Beuselinck,43 V. A. Bezzubov,39P. C. Bhat,50V. Bhatnagar,27C. Biscarat,20G. Blazey,52F. Blekman,43S. Blessing,49D. Bloch,19 K. Bloom,67A. Boehnlein,50D. Boline,62T. A. Bolton,59E. E. Boos,38G. Borissov,42T. Bose,77A. Brandt,78R. Brock,65

G. Brooijmans,70A. Bross,50D. Brown,81X. B. Bu,7N. J. Buchanan,49D. Buchholz,53M. Buehler,81V. Buescher,22 V. Bunichev,38S. Burdin,42,+T. H. Burnett,82C. P. Buszello,43J. M. Butler,62P. Calfayan,25S. Calvet,16J. Cammin,71 E. Carrera,49W. Carvalho,3B. C. K. Casey,50H. Castilla-Valdez,33S. Chakrabarti,18D. Chakraborty,52K. M. Chan,55 A. Chandra,48E. Cheu,45F. Chevallier,14D. K. Cho,62S. Choi,32B. Choudhary,28L. Christofek,77T. Christoudias,43 S. Cihangir,50D. Claes,67J. Clutter,58M. Cooke,50W. E. Cooper,50M. Corcoran,80F. Couderc,18M.-C. Cousinou,15 S. Cre´pe´-Renaudin,14V. Cuplov,59D. Cutts,77M. C´ wiok,30H. da Motta,2A. Das,45G. Davies,43K. De,78S. J. de Jong,35

E. De La Cruz-Burelo,64C. De Oliveira Martins,3J. D. Degenhardt,64F. De´liot,18M. Demarteau,50R. Demina,71 D. Denisov,50S. P. Denisov,39S. Desai,50H. T. Diehl,50M. Diesburg,50A. Dominguez,67H. Dong,72T. Dorland,82 A. Dubey,28L. V. Dudko,38L. Duflot,16S. R. Dugad,29D. Duggan,49A. Duperrin,15J. Dyer,65A. Dyshkant,52M. Eads,67

D. Edmunds,65J. Ellison,48V. D. Elvira,50Y. Enari,77S. Eno,61P. Ermolov,38,**H. Evans,54A. Evdokimov,73 V. N. Evdokimov,39A. V. Ferapontov,59T. Ferbel,71F. Fiedler,24F. Filthaut,35W. Fisher,50H. E. Fisk,50M. Fortner,52

H. Fox,42S. Fu,50S. Fuess,50T. Gadfort,70C. F. Galea,35C. Garcia,71A. Garcia-Bellido,82V. Gavrilov,37P. Gay,13 W. Geist,19D. Gele´,19W. Geng,15,65C. E. Gerber,51Y. Gershtein,49D. Gillberg,6G. Ginther,71N. Gollub,41B. Go´mez,8

A. Goussiou,82P. D. Grannis,72H. Greenlee,50Z. D. Greenwood,60E. M. Gregores,4G. Grenier,20Ph. Gris,13 J.-F. Grivaz,16A. Grohsjean,25S. Gru¨nendahl,50M. W. Gru¨newald,30F. Guo,72J. Guo,72G. Gutierrez,50P. Gutierrez,75 A. Haas,70N. J. Hadley,61P. Haefner,25S. Hagopian,49J. Haley,68I. Hall,65R. E. Hall,47L. Han,7K. Harder,44A. Harel,71

J. M. Hauptman,57R. Hauser,65J. Hays,43T. Hebbeker,21D. Hedin,52J. G. Hegeman,34A. P. Heinson,48U. Heintz,62 C. Hensel,22,xK. Herner,72G. Hesketh,63M. D. Hildreth,55R. Hirosky,81J. D. Hobbs,72B. Hoeneisen,12H. Hoeth,26 M. Hohlfeld,22S. Hossain,75P. Houben,34Y. Hu,72Z. Hubacek,10V. Hynek,9I. Iashvili,69R. Illingworth,50A. S. Ito,50

S. Jabeen,62M. Jaffre´,16S. Jain,75K. Jakobs,23C. Jarvis,61R. Jesik,43K. Johns,45C. Johnson,70M. Johnson,50 A. Jonckheere,50P. Jonsson,43A. Juste,50E. Kajfasz,15J. M. Kalk,60D. Karmanov,38P. A. Kasper,50I. Katsanos,70 D. Kau,49V. Kaushik,78R. Kehoe,79S. Kermiche,15N. Khalatyan,50A. Khanov,76A. Kharchilava,69Y. M. Kharzheev,36

D. Khatidze,70T. J. Kim,31M. H. Kirby,53M. Kirsch,21B. Klima,50J. M. Kohli,27J.-P. Konrath,23A. V. Kozelov,39 J. Kraus,65T. Kuhl,24A. Kumar,69A. Kupco,11T. Kurcˇa,20V. A. Kuzmin,38J. Kvita,9F. Lacroix,13D. Lam,55 S. Lammers,70G. Landsberg,77P. Lebrun,20W. M. Lee,50A. Leflat,38J. Lellouch,17J. Li,78,**L. Li,48Q. Z. Li,50 S. M. Lietti,5J. K. Lim,31J. G. R. Lima,52D. Lincoln,50J. Linnemann,65V. V. Lipaev,39R. Lipton,50Y. Liu,7Z. Liu,6

A. Lobodenko,40M. Lokajicek,11P. Love,42H. J. Lubatti,82R. Luna,3A. L. Lyon,50A. K. A. Maciel,2D. Mackin,80 R. J. Madaras,46P. Ma¨ttig,26C. Magass,21A. Magerkurth,64P. K. Mal,82H. B. Malbouisson,3S. Malik,67V. L. Malyshev,36 H. S. Mao,50Y. Maravin,59B. Martin,14R. McCarthy,72A. Melnitchouk,66L. Mendoza,8P. G. Mercadante,5M. Merkin,38 K. W. Merritt,50A. Meyer,21J. Meyer,22,xT. Millet,20J. Mitrevski,70R. K. Mommsen,44N. K. Mondal,29R. W. Moore,6

T. Moulik,58G. S. Muanza,20M. Mulhearn,70O. Mundal,22L. Mundim,3E. Nagy,15M. Naimuddin,50M. Narain,77 N. A. Naumann,35H. A. Neal,64J. P. Negret,8P. Neustroev,40H. Nilsen,23H. Nogima,3S. F. Novaes,5T. Nunnemann,25 V. O’Dell,50D. C. O’Neil,6G. Obrant,40C. Ochando,16D. Onoprienko,59N. Oshima,50N. Osman,43J. Osta,55R. Otec,10 G. J. Otero y Garzo´n,50M. Owen,44P. Padley,80M. Pangilinan,77N. Parashar,56S.-J. Park,22,xS. K. Park,31J. Parsons,70 R. Partridge,77N. Parua,54A. Patwa,73G. Pawloski,80B. Penning,23M. Perfilov,38K. Peters,44Y. Peters,26P. Pe´troff,16

M. Petteni,43R. Piegaia,1J. Piper,65M.-A. Pleier,22P. L. M. Podesta-Lerma,33,‡V. M. Podstavkov,50Y. Pogorelov,55 M.-E. Pol,2P. Polozov,37B. G. Pope,65A. V. Popov,39C. Potter,6W. L. Prado da Silva,3H. B. Prosper,49S. Protopopescu,73 J. Qian,64A. Quadt,22,xB. Quinn,66A. Rakitine,42M. S. Rangel,2K. Ranjan,28P. N. Ratoff,42P. Renkel,79S. Reucroft,63

P. Rich,44J. Rieger,54M. Rijssenbeek,72I. Ripp-Baudot,19F. Rizatdinova,76S. Robinson,43R. F. Rodrigues,3

M. Rominsky,75C. Royon,18P. Rubinov,50R. Ruchti,55G. Safronov,37G. Sajot,14A. Sa´nchez-Herna´ndez,33 M. P. Sanders,17B. Sanghi,50G. Savage,50L. Sawyer,60T. Scanlon,43D. Schaile,25R. D. Schamberger,72Y. Scheglov,40

H. Schellman,53T. Schliephake,26S. Schlobohm,82C. Schwanenberger,44A. Schwartzman,68R. Schwienhorst,65 J. Sekaric,49H. Severini,75E. Shabalina,51M. Shamim,59V. Shary,18A. A. Shchukin,39R. K. Shivpuri,28V. Siccardi,19

V. Simak,10V. Sirotenko,50P. Skubic,75P. Slattery,71D. Smirnov,55G. R. Snow,67J. Snow,74S. Snyder,73 S. So¨ldner-Rembold,44L. Sonnenschein,17A. Sopczak,42M. Sosebee,78K. Soustruznik,9B. Spurlock,78J. Stark,14 J. Steele,60V. Stolin,37D. A. Stoyanova,39J. Strandberg,64S. Strandberg,41M. A. Strang,69E. Strauss,72M. Strauss,75 R. Stro¨hmer,25D. Strom,53L. Stutte,50S. Sumowidagdo,49P. Svoisky,55A. Sznajder,3P. Tamburello,45A. Tanasijczuk,1

W. Taylor,6B. Tiller,25F. Tissandier,13M. Titov,18V. V. Tokmenin,36I. Torchiani,23D. Tsybychev,72B. Tuchming,18 C. Tully,68P. M. Tuts,70R. Unalan,65L. Uvarov,40S. Uvarov,40S. Uzunyan,52B. Vachon,6P. J. van den Berg,34 R. Van Kooten,54W. M. van Leeuwen,34N. Varelas,51E. W. Varnes,45I. A. Vasilyev,39M. Vaupel,26P. Verdier,20 L. S. Vertogradov,36M. Verzocchi,50D. Vilanova,18F. Villeneuve-Seguier,43P. Vint,43P. Vokac,10E. Von Toerne,59 M. Voutilainen,68,kR. Wagner,68H. D. Wahl,49L. Wang,61M. H. L. S. Wang,50J. Warchol,55G. Watts,82M. Wayne,55

G. Weber,24M. Weber,50L. Welty-Rieger,54A. Wenger,23,{N. Wermes,22M. Wetstein,61A. White,78D. Wicke,26 G. W. Wilson,58S. J. Wimpenny,48M. Wobisch,60D. R. Wood,63T. R. Wyatt,44Y. Xie,77S. Yacoob,53R. Yamada,50 W.-C. Yang,44T. Yasuda,50Y. A. Yatsunenko,36H. Yin,7K. Yip,73H. D. Yoo,77S. W. Youn,53J. Yu,78C. Zeitnitz,26

S. Zelitch,81T. Zhao,82B. Zhou,64J. Zhu,72M. Zielinski,71D. Zieminska,54A. Zieminski,54,**L. Zivkovic,70 V. Zutshi,52and E. G. Zverev38

(The DØ Collaboration)

1_{Universidad de Buenos Aires, Buenos Aires, Argentina} 2_{LAFEX, Centro Brasileiro de Pesquisas Fı´sicas, Rio de Janeiro, Brazil}

3

Universidade do Estado do Rio de Janeiro, Rio de Janeiro, Brazil

4_{Universidade Federal do ABC, Santo Andre´, Brazil}

5_{Instituto de Fı´sica Teo´rica, Universidade Estadual Paulista, Sa˜o Paulo, Brazil} 6_{University of Alberta, Edmonton, Alberta, Canada,}

Simon Fraser University, Burnaby, British Columbia, Canada, York University, Toronto, Ontario, Canada,

and McGill University, Montreal, Quebec, Canada

7_{University of Science and Technology of China, Hefei, People’s Republic of China} 8_{Universidad de los Andes, Bogota´, Colombia}

9_{Center for Particle Physics, Charles University, Prague, Czech Republic} 10_{Czech Technical University, Prague, Czech Republic}

11_{Center for Particle Physics, Institute of Physics, Academy of Sciences of the Czech Republic, Prague, Czech Republic} 12

Universidad San Francisco de Quito, Quito, Ecuador

13_{LPC, Universite´ Blaise Pascal, CNRS/IN2P3, Clermont, France}

14_{LPSC, Universite´ Joseph Fourier Grenoble 1, CNRS/IN2P3, Institut National Polytechnique de Grenoble, Grenoble, France} 15_{CPPM, Aix-Marseille Universite´, CNRS/IN2P3, Marseille, France}

16_{LAL, Universite´ Paris-Sud, IN2P3/CNRS, Orsay, France} 17_{LPNHE, IN2P3/CNRS, Universite´s Paris VI and VII, Paris, France}

18_{CEA, Irfu, SPP, Saclay, France}

19_{IPHC, Universite´ Louis Pasteur, CNRS/IN2P3, Strasbourg, France}

20_{IPNL, Universite´ Lyon 1, CNRS/IN2P3, Villeurbanne, France and Universite´ de Lyon, Lyon, France} 21_{III. Physikalisches Institut A, RWTH Aachen University, Aachen, Germany}

22_{Physikalisches Institut, Universita¨t Bonn, Bonn, Germany} 23_{Physikalisches Institut, Universita¨t Freiburg, Freiburg, Germany}

24_{Institut fu¨r Physik, Universita¨t Mainz, Mainz, Germany} 25_{Ludwig-Maximilians-Universita¨t Mu¨nchen, Mu¨nchen, Germany} 26_{Fachbereich Physik, University of Wuppertal, Wuppertal, Germany}

27_{Panjab University, Chandigarh, India} 28

Delhi University, Delhi, India

29_{Tata Institute of Fundamental Research, Mumbai, India} 30_{University College Dublin, Dublin, Ireland} 31_{Korea Detector Laboratory, Korea University, Seoul, Korea}

32_{SungKyunKwan University, Suwon, Korea} 33_{CINVESTAV, Mexico City, Mexico}

34_{FOM-Institute NIKHEF and University of Amsterdam/NIKHEF, Amsterdam, The Netherlands} 35_{Radboud University Nijmegen/NIKHEF, Nijmegen, The Netherlands}

36_{Joint Institute for Nuclear Research, Dubna, Russia} 37_{Institute for Theoretical and Experimental Physics, Moscow, Russia}

38_{Moscow State University, Moscow, Russia} 39_{Institute for High Energy Physics, Protvino, Russia} 40_{Petersburg Nuclear Physics Institute, St. Petersburg, Russia}

41_{Lund University, Lund, Sweden, Royal Institute of Technology and Stockholm University, Stockholm, Sweden,}

and Uppsala University, Uppsala, Sweden

42_{Lancaster University, Lancaster, United Kingdom} 43_{Imperial College, London, United Kingdom} 44_{University of Manchester, Manchester, United Kingdom}

45_{University of Arizona, Tucson, Arizona 85721, USA}

46_{Lawrence Berkeley National Laboratory and University of California, Berkeley, California 94720, USA} 47_{California State University, Fresno, California 93740, USA}

48_{University of California, Riverside, California 92521, USA} 49_{Florida State University, Tallahassee, Florida 32306, USA} 50_{Fermi National Accelerator Laboratory, Batavia, Illinois 60510, USA}

51_{University of Illinois at Chicago, Chicago, Illinois 60607, USA} 52_{Northern Illinois University, DeKalb, Illinois 60115, USA}

53_{Northwestern University, Evanston, Illinois 60208, USA} 54_{Indiana University, Bloomington, Indiana 47405, USA} 55_{University of Notre Dame, Notre Dame, Indiana 46556, USA}

56_{Purdue University Calumet, Hammond, Indiana 46323, USA} 57

Iowa State University, Ames, Iowa 50011, USA

58_{University of Kansas, Lawrence, Kansas 66045, USA} 59_{Kansas State University, Manhattan, Kansas 66506, USA} 60_{Louisiana Tech University, Ruston, Louisiana 71272, USA} 61_{University of Maryland, College Park, Maryland 20742, USA}

62_{Boston University, Boston, Massachusetts 02215, USA} 63_{Northeastern University, Boston, Massachusetts 02115, USA}

64_{University of Michigan, Ann Arbor, Michigan 48109, USA} 65_{Michigan State University, East Lansing, Michigan 48824, USA}

66_{University of Mississippi, University, Mississippi 38677, USA} 67_{University of Nebraska, Lincoln, Nebraska 68588, USA} 68_{Princeton University, Princeton, New Jersey 08544, USA} 69_{State University of New York, Buffalo, New York 14260, USA}

70_{Columbia University, New York, New York 10027, USA} 71_{University of Rochester, Rochester, New York 14627, USA} 72_{State University of New York, Stony Brook, New York 11794, USA}

73_{Brookhaven National Laboratory, Upton, New York 11973, USA} 74_{Langston University, Langston, Oklahoma 73050, USA} 75_{University of Oklahoma, Norman, Oklahoma 73019, USA} 76_{Oklahoma State University, Stillwater, Oklahoma 74078, USA}

77_{Brown University, Providence, Rhode Island 02912, USA} 78_{University of Texas, Arlington, Texas 76019, USA} 79_{Southern Methodist University, Dallas, Texas 75275, USA}

80

Rice University, Houston, Texas 77005, USA

81_{University of Virginia, Charlottesville, Virginia 22901, USA} 82_{University of Washington, Seattle, Washington 98195, USA}

(Received 14 July 2008; published 29 October 2008)

We measure the mass of the top quark using top-quark pair candidate events in the leptonþ jets channel from data corresponding to 1 fb
1of integrated luminosity collected by the D0 experiment at the Fermilab Tevatron collider. We use a likelihood technique that reduces the jet energy scale uncertainty by combining an in situ jet energy calibration with the independent constraint on the jet energy scale (JES) from the calibration derived using photonþ jets and dijet samples. We find the mass of the top quark to be 171:5  1:8ðstat: þ JESÞ  1:1ðsyst:Þ GeV.

DOI:10.1103/PhysRevLett.101.182001 PACS numbers: 14.65.Ha, 12.15.Ff

Since the discovery of the top quark in 1995 [1], a substantial effort has gone into measuring and understand-ing its properties. Its large mass suggests a unique role in the mechanism of electroweak symmetry breaking. Through radiative corrections, a precise measurement of the top-quark mass, together with that of the W boson, allows indirect constraints to be placed on the mass of the standard model Higgs boson [2]. A precise knowledge of the top-quark mass could also provide a useful constraint to possible extensions of the standard model. It is therefore of great importance to continue improving measurements of the top-quark mass [3,4].

In this Letter, we present the most precise single mea-surement of the top-quark mass from Run II of the Fermilab Tevatron collider. It uses a matrix element (ME) method with an in situ jet energy calibration based on a global factor used to scale all jet energies and thereby the invariant mass of the hadronic W boson [3,5]. This mass is constrained to the well-known value of 80.4 GeV through the Breit-Wigner function for the hadronic W boson in the ME for t
t production. The jet energy scale is further constrained to the standard scale derived from photonþ jets and dijet samples within its uncertainties through the use of a prior probability distribution. This analysis is based on data collected by the D0 detector [6] comprising 1 fb
1of integrated luminosity from p
p colli-sions atpffiffiffis¼ 1:96 TeV.

The top quark is assumed to always decay into a W boson and a b quark producing a WþW
b
b final state from t
t production. This analysis is based on the lepton þ jets channel with one W boson decaying via W ! ‘
and the other via W ! q
q0. This channel is characterized by a lepton with large transverse momentum (pT), large

mo-mentum imbalance due to the undetected neutrino (p6 T),

and four high-pT jets. Events are selected for this analysis

by requiring exactly one isolated electron (muon) with pT> 20 GeV and jj < 1:1 (jj < 2), p6 T > 20 GeV,

and exactly four jets with pT> 20 GeV and jj < 2:5,

where the pseudorapidity  ¼
ln½tanð=2Þ, and  is the polar angle with respect to the proton beam direction. Multijet background, typically originating from lepton or jet energy mis-measurements, is further suppressed by requiring the lepton direction and p6 Tvector to be separated

in azimuth. Jets are reconstructed using a cone algorithm [7] with radius R ¼pffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiffiðyÞ2þ ðÞ2¼ 0:5 where the y is the rapidity. Jet energies are corrected to the particle level using corrections derived from photonþ jet and dijet samples. Jets containing a muon are assumed to originate from semileptonic b quark decays and corrected by the muon momentum and average neutrino energy. At least one jet is required to be tagged by a neural-network based algorithm [8] as a b-jet candidate. The tagging efficiency for b jets is 50% with a misidentification rate of 1% from light jets. A total of 220 events, split equally between the electron and muon channels, satisfying these criteria is selected.

The top-quark mass is determined from the data sample with a likelihood method based on per-event probability densities (p.d.’s) constructed from the MEs of the processes contributing to the observed events. Assuming only two processes, t
t and W þ jets production, the p.d. to observe an event with measured variables x is

Pevt¼ AðxÞ½fPsigðx; mt; kjesÞ þ ð1
fÞPbkgðx; kjesÞ;

where the top-quark mass mt, jet energy scale factor kjes

dividing the energies of all jets, and observed signal frac-tion f are the parameters to determine from data. Psigand

Pbkgare, respectively, p.d.’s for t
t and W þ jets production.

Multijet events satisfy Pbkg Psig and are also

repre-sented by Pbkg. AðxÞ is a function only of x and accounts

for the geometrical acceptance and efficiencies.

Psig and Pbkg are calculated by integrating over all

possible parton states leading to the measured set x. In addition to the partonic final state described by the varia-bles y, these states include the initial state partons carrying momenta q1 and q2 in the colliding p and
p. The

integra-tion involves a convoluintegra-tion of the partonic differential cross section dðy; mtÞ with the p.d.’s for the initial state

partons fðqiÞ and the transfer function Wðy; x; kjesÞ,

Psig¼ 1

N Z X

dðy; mtÞdq1dq2fðq1Þfðq2ÞWðy; x; kjesÞ;

where the sum runs over all possible initial state parton flavor combinations. fðqiÞ includes parton density

func-tions (PDFs) for finding a parton of a given flavor and longitudinal momentum fraction in the p or
p (CTEQ6L1 [9]) and parameterizations of the p.d.’s for the transverse components of qiderived fromPYTHIA[10]. Jet

fragmen-tation effects and experimental resolution are taken into account by Wðy; x; kjesÞ, representing the p.d. for the

mea-sured set x to have arisen from the partonic set y. The normalization factor N, defined as the expected observed cross section for a given (mt, kjes), ensures AðxÞPsig (and

ultimately Pevt) is normalized to unity.

The differential cross section term in Psigis calculated

using the leading order ME for q
q ! t
t. After all energy and momentum constraints are taken into account, this term is integrated over the energy associated with one of the quarks from the hadronic W boson decay, the masses of the two W bosons and two top quarks, and the energy (1=pT) of the electron (muon). It is summed over 24

possible jet-parton assignments each carrying a b-jet tag-ging weight [11] and over the neutrino solutions. Wðy; x; kjesÞ is the product of five terms for the four jets

and one charged lepton. The jet terms are parameterized in terms of jet energy with a function involving the sum of two Gaussians whose parameters depend linearly on parton energy. The term for the charged lepton is parameterized as a Gaussian distribution in energy (1=pT) for electrons

fully simulated Monte Carlo (MC) events. The normaliza-tion cross section t
tobs¼RAðxÞPsigdx ¼ t
tðmtÞ 

hAðmt; kjesÞi is calculated using the total cross section

corresponding to the ME used and the mean acceptance for events whose dependencies on mt and kjes are

deter-mined from MC events.

The differential cross section term in Pbkg is calculated

using the W þ 4 jets MEs provided byVECBOS[12]. The integration is performed over the energies of the four partons producing the jets, the W boson mass, and the energy (1=pT) of the electron (muon) summing over 24

possible jet-parton assignments and two neutrino solutions. The transverse momenta of the initial state partons are assumed to be zero.

Psig and Pbkg are calculated using MC techniques on a

grid in (mt, kjes) having spacings of 1.5 GeV and 0.015,

respectively. At each grid point, a likelihood function, Lðx; mt; kjes; fÞ, is constructed from the product of the

individual event p.d.’s (Pevt) and f is determined by

minimizing
lnL at that point. Lðx; m_t; kjesÞ is then

projected onto the mt and kjes axes according to

Lðx; mtÞ ¼

R

Lðx; mt; kjesÞGðkjesÞdkjes and Lðx; kjesÞ ¼

R

Lðx; mt; kjesÞdmt. The prior GðkjesÞ is a Gaussian

func-tion centered at kjes¼ 1 with width  ¼ 0:019 determined

from the photonþ jets and dijet samples used in the stan-dard jet energy scale calibration. Best estimates of mtand

kjes and their uncertainties are then extracted from the

mean and rms of Lðx; mtÞ and Lðx; kjesÞ.

The measurement technique described above is cali-brated using MC events produced with theALPGEN event generator [13] employingPYTHIAfor parton showering and hadronization and implementing the MLM matching scheme [14]. All generated events are processed by a full

GEANT [15] detector simulation followed by the same reconstruction and analysis programs used on data. Figure1shows comparisons of the 2-jet and 3-jet invariant mass distributions between data and MC using t
t events with a true top-quark mass (mtruet ) of 170 GeV. These are

calculated using jets assigned as the decay products of the top-quark and W boson from the hadronic branch in the permutation with the largest weight (defined as the product of Psig and the b-jet tagging weight) around the peak of

Lðx; mt; kjesÞ. MC distributions are normalized to data

dis-tributions with f ¼ 0:74 determined from data. The back-ground includes simulated W þ jets events and data events selected from a multijet enriched sample. The latter com-prises 12% of the total background based on estimates from data. The estimated number of t
t events (e þ jets: 91  9,  þ jets: 71  8) agrees with the expectation (e þ jets: 89 6,  þ jets: 73  5).

Five t
t MC samples are generated with mtruet ¼ 160, 165,

170, 175, and 180 GeV, with six more produced from three of these by scaling all jet energies by5%. Psigand Pbkg

are calculated for these events from which pseudo-experiments fixed to the number of data events are ran-domly drawn with a signal fraction fluctuated according to a binomial distribution around that determined from data. The mean values of mt and kjes for 1000

pseudo-experiments are shown in Fig. 2 as functions of the true values and fitted to a straight line. The average widths of the mt and kjes pull distributions are 1.0 and 1.1,

respec-tively. The pull is defined as the deviation of a measure-ment from the mean of all measuremeasure-ments divided by the uncertainty of the measurement per pseudo-experiment. The measured uncertainties in data are corrected by the deviation of the average pull width from 1.0.

Lðx; mtÞ and Lðx; kjesÞ for the selected data samples are

calibrated according to the parameterizations shown in Fig.2. Lðx; mtÞ is shown in Fig.3(a)with a measured mt¼

171:5  1:8ðstat: þ JESÞ GeV. The measured kjes¼

1:030  0:017 represents a 1:2 shift from kjes¼ 1 where

 is the sum in quadrature of the width of GðkjesÞ and the

uncertainty of the measured kjes. Figure3(b)compares the

measured uncertainty for mtwith the expected uncertainty

distribution from pseudo-experiments in MC assuming mtruet ¼ 170 GeV.

To verify the in situ jet energy calibration, we repeat the analysis on data by fixing kjes to the measured value and

removing the W boson mass constraint, replacing Lðx; mt; kjes; fÞ with Lðx; mt; mW; fÞ. Psig and Pbkg are

now calculated on a grid in (mt, mW) having spacings of

1.5 and 1 GeV, respectively. Lðx; mtÞ and Lðx; mWÞ are

calculated in the same way as for the grid in (mt, kjes)

(GeV) 2j m 20 40 60 80 100120140160180 Events / 5 GeV 0 5 10 15 20 25 30 35 40 45 20 40 60 80 100120140160180 0 5 10 15 20 25 30 35 40 45 data t t W+jet multijet -1 DØ, 1 fb (GeV) 3j m 50 100 150 200 250 300 350 Events / 10 GeV 0 10 20 30 40 50 50 100 150 200 250 300 350 0 10 20 30 40 50 data t t W+jet multijet -1 DØ, 1 fb

FIG. 1 (color online). Comparison between data and MC 2-jet (m2j) and 3-jet (m3j) invariant mass distributions.

- 170 GeV true t m -10 -5 0 5 10 - 170 GeVt m -10 -5 0 5 10 true t m × = 0.97 t m + 1.61 GeV - 1 true jes k -0.05 0 0.05 - 1 jes k -0.05 0 0.05 true jes = 0.95 k jes k - 0.01 =165 GeV true t m =170 GeV true t m =175 GeV true t m

FIG. 2. Mean values of mtand kjesfrom ensemble tests versus

true values parameterized by straight lines. Dashed lines repre-sent identical fitted and true values.

except that no prior probability distribution is used for Lðx; mtÞ. We find mW ¼ 80:3  1:0 GeV which is

consis-tent with the constraint of 80.4 GeV.

Systematic uncertainties are evaluated for three catego-ries. The first category involves the modeling of MC t
t and W þ jets events and includes uncertainties in the modeling of extra jets due to radiation in t
t events, the distribution shapes and the heavy flavor fraction in W þ jets events, b fragmentation, and the PDFs used in generating events. The second category is associated with the simulation of detector response and includes possible effects due to the energy and jj dependence of the jet energy scale unac-counted for by the in situ calibration, uncertainties in the modeling of the relative calorimeter response to b and light quark jets, and uncertainties associated with the simulation of jet energy resolution and reconstruction efficiency, muon pTresolution, and trigger efficiency. The third

cate-gory is related to assumptions made in the method and uncertainties in the calibration and includes possible effects due to the exclusion of multijet events and non-leptonþ jets t
t events from the calibration procedure, uncertainties in the signal fraction used in ensemble tests, and uncertainties associated with the parameters defining the calibration curve. Contributions from all these sources are summarized in Table I and sum in quadrature to 1:1 GeV.

The leading sources of uncertainty in TableIare those associated with the b=light response ratio and signal mod-eling. The first of these is evaluated by estimating the possible difference in this ratio between data and MC and scaling the energies of all jets matched to b quarks in a MC t
t sample by this amount. The analysis is repeated for this sample and the difference in mt from that of the

unscaled sample taken as the uncertainty. The uncertainty associated with the modeling of additional jets in t
t events is evaluated using both data and MC samples. Using MC t
t events, the fraction of t
t signal events with  5 jets is varied such that the ratio of 4-jet to 5-jet events in MC matches that in data including its uncertainties. The differ-ence in the resulting mtfrom that of the default sample is

taken as the uncertainty. Using data, this is done through ensemble tests in which a fixed number of 5-jet events

not used in the measurement are randomly drawn for each experiment and combined with the default sample of 4-jet events. The ensemble tests are repeated for different frac-tions of 5-jet events constituting up to 30% of each experiment. mt for the default sample is compared with

the mean from each ensemble test and the largest differ-ence taken as the systematic uncertainty. Both procedures yield consistent estimates for this systematic uncertainty.

In summary, we present a measurement of the top-quark mass using t
t lepton þ jets events from 1 fb
1 of data collected by the D0 experiment. Using a ME technique combining an in situ calibration of the jet energy scale with the calibration based on the photonþ jets and dijet samples gives us

mt¼ 171:5  1:8ðstat: þ JESÞ  1:1ðsyst:Þ GeV;

representing the most precise single measurement to date. We thank the staffs at Fermilab and collaborating insti-tutions, and acknowledge support from the DOE and NSF (USA); CEA and CNRS/IN2P3 (France); FASI, Rosatom, and RFBR (Russia); CNPq, FAPERJ, FAPESP, and FUNDUNESP (Brazil); DAE and DST (India); Colciencias (Colombia); CONACyT (Mexico); KRF and KOSEF (Korea); CONICET and UBACyT (Argentina); FOM (The Netherlands); STFC (United Kingdom); MSMT and GACR (Czech Republic); CRC Program, CFI, NSERC and WestGrid Project (Canada); BMBF and DFG (Germany); SFI (Ireland); The Swedish Research Council (Sweden); CAS and CNSF (China); and the Alexander von Humboldt Foundation (Germany).

TABLE I. Summary of systematic uncertainties (symmetrized based on the larger of the two values in each direction).

Source Uncertainty (GeV)

Physics modeling: Signal modeling 0:40 PDF uncertainty 0:14 Background modeling 0:10 b-fragmentation 0:03 Detector Modeling:

b=light response ratio 0:83

Jet identification and resolution 0:26

Trigger 0:19

Residual jet energy scale 0:10

Muon resolution 0:10 Method: MC calibration 0:26 b-tagging efficiency 0:15 Multijet contamination 0:14 Signal contamination 0:13 Signal fraction 0:09 Total 1:07 (GeV) t m 150 160 170 180 190 max )/L t L(m 0 0.5 1 1.8 GeV ± = 171.5 t m -1 DØ, 1 fb (a) ) [GeV] t (m σ 1 1.5 2 2.5 3 3.5 Ensembles / 0.1 GeV 0 100 200 300 _-1 DØ, 1 fb (b)

FIG. 3. (a) Projection of data likelihood onto the mtaxis with

best estimate shown. (b) Expected uncertainty distribution for mt

*Visitor from Augustana College, Sioux Falls, SD, USA.

+_{Visitor from The University of Liverpool, Liverpool,} UK.

‡_{Visitor from ECFM, Universidad Autonoma de Sinaloa,} Culiaca´n, Mexico.

x_{Visitor from II. Physikalisches Institut,} Georg-August-University, Go¨ttingen, Germany.

k_{Visitor from Helsinki Institute of Physics, Helsinki,} Finland.

{_{Visitor from Universita¨t Zu¨rich, Zu¨rich, Switzerland.}

**Deceased.

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