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Measurement of the Forward-Backward Charge Asymmetry in Top-Quark Pair Production

V. M. Abazov,36B. Abbott,76M. Abolins,66B. S. Acharya,29M. Adams,52T. Adams,50E. Aguilo,6S. H. Ahn,31 M. Ahsan,60G. D. Alexeev,36G. Alkhazov,40A. Alton,65,*G. Alverson,64G. A. Alves,2M. Anastasoaie,35L. S. Ancu,35

T. Andeen,54S. Anderson,46B. Andrieu,17M. S. Anzelc,54Y. Arnoud,14M. Arov,61M. Arthaud,18A. Askew,50 B. A˚ sman,41A. C. S. Assis Jesus,3O. Atramentov,50C. Autermann,21C. Avila,8C. Ay,24F. Badaud,13A. Baden,62 L. Bagby,53B. Baldin,51D. V. Bandurin,60S. Banerjee,29P. Banerjee,29E. Barberis,64A.-F. Barfuss,15P. Bargassa,81

P. Baringer,59J. Barreto,2J. F. Bartlett,51U. Bassler,18D. Bauer,44S. Beale,6A. Bean,59M. Begalli,3M. Begel,72 C. Belanger-Champagne,41L. Bellantoni,51A. Bellavance,51J. A. Benitez,66S. B. Beri,27G. Bernardi,17R. Bernhard,23 I. Bertram,43M. Besanc¸on,18R. Beuselinck,44V. A. Bezzubov,39P. C. Bhat,51V. Bhatnagar,27C. Biscarat,20G. Blazey,53

F. Blekman,44S. Blessing,50D. Bloch,19K. Bloom,68A. Boehnlein,51D. Boline,63T. A. Bolton,60G. Borissov,43 T. Bose,78A. Brandt,79R. Brock,66G. Brooijmans,71A. Bross,51D. Brown,82N. J. Buchanan,50D. Buchholz,54 M. Buehler,82V. Buescher,22V. Bunichev,38S. Burdin,43,†S. Burke,46T. H. Burnett,83C. P. Buszello,44J. M. Butler,63

P. Calfayan,25S. Calvet,16J. Cammin,72W. Carvalho,3B. C. K. Casey,51N. M. Cason,56H. Castilla-Valdez,33 S. Chakrabarti,18D. Chakraborty,53K. M. Chan,56K. Chan,6A. Chandra,49F. Charles,19,‡E. Cheu,46F. Chevallier,14

D. K. Cho,63S. Choi,32B. Choudhary,28L. Christofek,78T. Christoudias,44S. Cihangir,51D. Claes,68Y. Coadou,6 M. Cooke,81W. E. Cooper,51M. Corcoran,81F. Couderc,18M.-C. Cousinou,15S. Cre´pe´-Renaudin,14D. Cutts,78

M. C´ wiok,30H. da Motta,2A. Das,46G. Davies,44K. De,79S. J. de Jong,35E. De La Cruz-Burelo,65

C. De Oliveira Martins,3J. D. Degenhardt,65F. De´liot,18M. Demarteau,51R. Demina,72D. Denisov,51S. P. Denisov,39 S. Desai,51H. T. Diehl,51M. Diesburg,51A. Dominguez,68H. Dong,73L. V. Dudko,38L. Duflot,16S. R. Dugad,29 D. Duggan,50A. Duperrin,15J. Dyer,66A. Dyshkant,53M. Eads,68D. Edmunds,66J. Ellison,49V. D. Elvira,51Y. Enari,78

S. Eno,62P. Ermolov,38H. Evans,55A. Evdokimov,74V. N. Evdokimov,39A. V. Ferapontov,60T. Ferbel,72F. Fiedler,24 F. Filthaut,35W. Fisher,51H. E. Fisk,51M. Ford,45M. Fortner,53H. Fox,23S. Fu,51S. Fuess,51T. Gadfort,83C. F. Galea,35 E. Gallas,51E. Galyaev,56C. Garcia,72A. Garcia-Bellido,83V. Gavrilov,37P. Gay,13W. Geist,19D. Gele´,19C. E. Gerber,52

Y. Gershtein,50D. Gillberg,6G. Ginther,72N. Gollub,41B. Go´mez,8A. Goussiou,56P. D. Grannis,73H. Greenlee,51 Z. D. Greenwood,61E. M. Gregores,4G. Grenier,20Ph. Gris,13J.-F. Grivaz,16A. Grohsjean,25S. Gru¨nendahl,51 M. W. Gru¨newald,30J. Guo,73F. Guo,73P. Gutierrez,76G. Gutierrez,51A. Haas,71N. J. Hadley,62P. Haefner,25 S. Hagopian,50J. Haley,69I. Hall,66R. E. Hall,48L. Han,7K. Hanagaki,51P. Hansson,41K. Harder,45A. Harel,72

R. Harrington,64J. M. Hauptman,58R. Hauser,66J. Hays,44T. Hebbeker,21D. Hedin,53J. G. Hegeman,34 J. M. Heinmiller,52A. P. Heinson,49U. Heintz,63C. Hensel,59K. Herner,73G. Hesketh,64M. D. Hildreth,56R. Hirosky,82 J. D. Hobbs,73B. Hoeneisen,12H. Hoeth,26M. Hohlfeld,22S. J. Hong,31S. Hossain,76P. Houben,34Y. Hu,73Z. Hubacek,10 V. Hynek,9I. Iashvili,70R. Illingworth,51A. S. Ito,51S. Jabeen,63M. Jaffre´,16S. Jain,76K. Jakobs,23C. Jarvis,62R. Jesik,44

K. Johns,46C. Johnson,71M. Johnson,51A. Jonckheere,51P. Jonsson,44A. Juste,51D. Ka¨fer,21E. Kajfasz,15 A. M. Kalinin,36J. R. Kalk,66J. M. Kalk,61S. Kappler,21D. Karmanov,38P. Kasper,51I. Katsanos,71D. Kau,50R. Kaur,27

V. Kaushik,79R. Kehoe,80S. Kermiche,15N. Khalatyan,51A. Khanov,77A. Kharchilava,70Y. M. Kharzheev,36 D. Khatidze,71H. Kim,32T. J. Kim,31M. H. Kirby,54M. Kirsch,21B. Klima,51J. M. Kohli,27J.-P. Konrath,23M. Kopal,76

V. M. Korablev,39A. V. Kozelov,39D. Krop,55T. Kuhl,24A. Kumar,70S. Kunori,62A. Kupco,11T. Kurcˇa,20J. Kvita,9 F. Lacroix,13D. Lam,56S. Lammers,71G. Landsberg,78P. Lebrun,20W. M. Lee,51A. Leflat,38F. Lehner,42J. Lellouch,17

J. Leveque,46P. Lewis,44J. Li,79Q. Z. Li,51L. Li,49S. M. Lietti,5J. G. R. Lima,53D. Lincoln,51J. Linnemann,66 V. V. Lipaev,39R. Lipton,51Y. Liu,7Z. Liu,6L. Lobo,44A. Lobodenko,40M. Lokajicek,11P. Love,43H. J. Lubatti,83 A. L. Lyon,51A. K. A. Maciel,2D. Mackin,81R. J. Madaras,47P. Ma¨ttig,26C. Magass,21A. Magerkurth,65P. K. Mal,56

H. B. Malbouisson,3S. Malik,68V. L. Malyshev,36H. S. Mao,51Y. Maravin,60B. Martin,14R. McCarthy,73 A. Melnitchouk,67A. Mendes,15L. Mendoza,8P. G. Mercadante,5M. Merkin,38K. W. Merritt,51J. Meyer,22,xA. Meyer,21 T. Millet,20J. Mitrevski,71J. Molina,3R. K. Mommsen,45N. K. Mondal,29R. W. Moore,6T. Moulik,59G. S. Muanza,20 M. Mulders,51M. Mulhearn,71O. Mundal,22L. Mundim,3E. Nagy,15M. Naimuddin,51M. Narain,78N. A. Naumann,35 H. A. Neal,65J. P. Negret,8P. Neustroev,40H. Nilsen,23H. Nogima,3A. Nomerotski,51S. F. Novaes,5T. Nunnemann,25

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M.-E. Pol,2P. Polozov,37B. G. Pope,66A. V. Popov,39C. Potter,6W. L. Prado da Silva,3H. B. Prosper,50S. Protopopescu,74 J. Qian,65A. Quadt,22,xB. Quinn,67A. Rakitine,43M. S. Rangel,2K. Ranjan,28P. N. Ratoff,43P. Renkel,80S. Reucroft,64

P. Rich,45M. Rijssenbeek,73I. Ripp-Baudot,19F. Rizatdinova,77S. Robinson,44R. F. Rodrigues,3M. Rominsky,76 C. Royon,18P. Rubinov,51R. Ruchti,56G. Safronov,37G. Sajot,14A. Sa´nchez-Herna´ndez,33M. P. Sanders,17A. Santoro,3

G. Savage,51L. Sawyer,61T. Scanlon,44D. Schaile,25R. D. Schamberger,73Y. Scheglov,40H. Schellman,54 P. Schieferdecker,25T. Schliephake,26C. Schwanenberger,45A. Schwartzman,69R. Schwienhorst,66J. Sekaric,50 H. Severini,76E. Shabalina,52M. Shamim,60V. Shary,18A. A. Shchukin,39R. K. Shivpuri,28V. Siccardi,19V. Simak,10

V. Sirotenko,51P. Skubic,76P. Slattery,72D. Smirnov,56J. Snow,75G. R. Snow,68S. Snyder,74S. So¨ldner-Rembold,45 L. Sonnenschein,17A. Sopczak,43M. Sosebee,79K. Soustruznik,9M. Souza,2B. Spurlock,79J. Stark,14J. Steele,61 V. Stolin,37D. A. Stoyanova,39J. Strandberg,65S. Strandberg,41M. A. Strang,70M. Strauss,76E. Strauss,73R. Stro¨hmer,25

D. Strom,54L. Stutte,51S. Sumowidagdo,50P. Svoisky,56A. Sznajder,3M. Talby,15P. Tamburello,46A. Tanasijczuk,1 W. Taylor,6J. Temple,46B. Tiller,25F. Tissandier,13M. Titov,18V. V. Tokmenin,36T. Toole,62I. Torchiani,23T. Trefzger,24 D. Tsybychev,73B. Tuchming,18C. Tully,69P. M. Tuts,71R. Unalan,66S. Uvarov,40L. Uvarov,40S. Uzunyan,53B. Vachon,6 P. J. van den Berg,34R. Van Kooten,55W. M. van Leeuwen,34N. Varelas,52E. W. Varnes,46I. A. Vasilyev,39M. Vaupel,26

P. Verdier,20L. S. Vertogradov,36M. Verzocchi,51F. Villeneuve-Seguier,44P. Vint,44P. Vokac,10E. Von Toerne,60 M. Voutilainen,68,{R. Wagner,69H. D. Wahl,50L. Wang,62M. H. L. S Wang,51J. Warchol,56G. Watts,83M. Wayne,56

M. Weber,51G. Weber,24A. Wenger,23,**N. Wermes,22M. Wetstein,62A. White,79D. Wicke,26G. W. Wilson,59 S. J. Wimpenny,49M. Wobisch,61D. R. Wood,64T. R. Wyatt,45Y. Xie,78S. Yacoob,54R. Yamada,51M. Yan,62T. Yasuda,51 Y. A. Yatsunenko,36K. Yip,74H. D. Yoo,78S. W. Youn,54J. Yu,79A. Zatserklyaniy,53C. Zeitnitz,26T. Zhao,83B. Zhou,65

J. Zhu,73M. Zielinski,72D. Zieminska,55A. Zieminski,55,‡L. Zivkovic,71V. Zutshi,53and E. G. Zverev38

(D0 Collaboration)

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

3Universidade do Estado do Rio de Janeiro, Rio de Janeiro, Brazil 4Universidade Federal do ABC, Santo Andre´, Brazil

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

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

and McGill University, Montreal, Quebec, Canada

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

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

11Center for Particle Physics, Institute of Physics, Academy of Sciences of the Czech Republic, Prague, Czech Republic 12Universidad San Francisco de Quito, Quito, Ecuador

13Laboratoire de Physique Corpusculaire, IN2P3-CNRS, Universite´ Blaise Pascal, Clermont-Ferrand, France 14Laboratoire de Physique Subatomique et de Cosmologie, IN2P3-CNRS, Universite de Grenoble 1, Grenoble, France

15CPPM, IN2P3-CNRS, Universite´ de la Me´diterrane´e, Marseille, France

16Laboratoire de l’Acce´le´rateur Line´aire, IN2P3-CNRS et Universite´ Paris-Sud, Orsay, France 17LPNHE, IN2P3-CNRS, Universite´s Paris VI and VII, Paris, France

18DAPNIA/Service de Physique des Particules, CEA, Saclay, France

19IPHC, Universite´ Louis Pasteur et Universite´ de Haute Alsace, CNRS, IN2P3, Strasbourg, France 20IPNL, Universite´ Lyon 1, CNRS/IN2P3, Villeurbanne, France

and Universite´ de Lyon, Lyon, France

21III. Physikalisches Institut A, RWTH Aachen, Aachen, Germany 22Physikalisches Institut, Universita¨t Bonn, Bonn, Germany 23Physikalisches Institut, Universita¨t Freiburg, Freiburg, Germany

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

27Panjab University, Chandigarh, India 28Delhi University, Delhi, India

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30University College Dublin, Dublin, Ireland 31Korea Detector Laboratory, Korea University, Seoul, Korea

32SungKyunKwan University, Suwon, Korea 33CINVESTAV, Mexico City, Mexico

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

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

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

41Lund University, Lund, Sweden, Royal Institute of Technology and Stockholm University, Stockholm, Sweden,

and Uppsala University, Uppsala, Sweden

42Physik Institut der Universita¨t Zu¨rich, Zu¨rich, Switzerland 43Lancaster University, Lancaster, United Kingdom

44Imperial College, London, United Kingdom 45University of Manchester, Manchester, United Kingdom

46University of Arizona, Tucson, Arizona 85721, USA

47Lawrence Berkeley National Laboratory and University of California, Berkeley, California 94720, USA 48California State University, Fresno, California 93740, USA

49University of California, Riverside, California 92521, USA 50Florida State University, Tallahassee, Florida 32306, USA 51Fermi National Accelerator Laboratory, Batavia, Illinois 60510, USA

52University of Illinois at Chicago, Chicago, Illinois 60607, USA 53Northern Illinois University, DeKalb, Illinois 60115, USA

54Northwestern University, Evanston, Illinois 60208, USA 55Indiana University, Bloomington, Indiana 47405, USA 56University of Notre Dame, Notre Dame, Indiana 46556, USA

57Purdue University Calumet, Hammond, Indiana 46323, USA 58Iowa State University, Ames, Iowa 50011, USA 59University of Kansas, Lawrence, Kansas 66045, USA 60Kansas State University, Manhattan, Kansas 66506, USA 61Louisiana Tech University, Ruston, Louisiana 71272, USA 62University of Maryland, College Park, Maryland 20742, USA

63Boston University, Boston, Massachusetts 02215, USA 64Northeastern University, Boston, Massachusetts 02115, USA

65University of Michigan, Ann Arbor, Michigan 48109, USA 66Michigan State University, East Lansing, Michigan 48824, USA

67University of Mississippi, University, Mississippi 38677, USA 68University of Nebraska, Lincoln, Nebraska 68588, USA 69Princeton University, Princeton, New Jersey 08544, USA 70State University of New York, Buffalo, New York 14260, USA

71Columbia University, New York, New York 10027, USA 72University of Rochester, Rochester, New York 14627, USA 73State University of New York, Stony Brook, New York 11794, USA

74Brookhaven National Laboratory, Upton, New York 11973, USA 75Langston University, Langston, Oklahoma 73050, USA 76University of Oklahoma, Norman, Oklahoma 73019, USA 77Oklahoma State University, Stillwater, Oklahoma 74078, USA

78Brown University, Providence, Rhode Island 02912, USA 79University of Texas, Arlington, Texas 76019, USA 80Southern Methodist University, Dallas, Texas 75275, USA

81Rice University, Houston, Texas 77005, USA 82University of Virginia, Charlottesville, Virginia 22901, USA

83University of Washington, Seattle, Washington 98195, USA

(Received 7 December 2007; published 9 April 2008)

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measure the asymmetry for different jet multiplicities. The result is also used to set upper limits onttX

production via aZ0resonance.

DOI:10.1103/PhysRevLett.100.142002 PACS numbers: 12.38.Qk, 12.60.i, 13.85.t, 13.87.Ce

At lowest order in quantum chromodynamics (QCD), the standard model (SM) predicts that the kinematic dis-tributions inpp !ttXproduction are charge symmet-ric. But this symmetry is accidental, as the initialpp state is not an eigenstate of charge conjugation. Next-to-leading order calculations predict forward-backward asymmetries of (5–10)% [1,2], but recent next-to-next-to-leading order calculations predict significant corrections forttjet pro-duction [3]. The asymmetry arises mainly from interfer-ence between contributions symmetric and antisymmetric under the exchanget$t[1], e.g., between initial and final state gluon radiation in qq !ttg. It depends on the region of phase space being probed and, in particular, on the production of an additional jet [2]. The small asymme-tries expected in the SM make this a sensitive probe for new physics [4].

A charge asymmetry inpp !ttXcan be observed as a forward-backward production asymmetry. The signed difference between the rapidities [5] of the t and t, yytyt, reflects the asymmetry in tt production.

We define the integrated charge asymmetry asAfb Nf Nb=NfNb, whereNf(Nb) is the number of events with

a positive (negative)y.

This Letter describes the first measurement of Afb in pp !ttX production. The 0:9 fb1 data sample used

was collected atps1:96 TeVwith the D0 detector [6], using triggers that required a jet and an electron or muon. In the leptonjets final state of thettsystem, one of the twoWbosons from thettpair decays into hadronic jets and the other into leptons, yielding a signature of two bjets, two light-flavor jets, an isolated lepton, and missing trans-verse energy (E6 T). This decay mode is well suited for this measurement, as it combines a large branching fraction

(34%) with high signal purity, the latter a consequence

of requiring an isolated electron or muon with large trans-verse momentum (pT). The main background is fromW

jets and multijet production. This channel allows accurate reconstruction of thetandtdirections in the collision rest frame, and the charge of the electron or muon distinguishes between thetandtquarks.

The dependence ofAfbon the region of phase space, as

calculated by theMC@NLOevent generator [7], shows that acceptance can strongly affect the asymmetry. In particu-lar, the largest acceptance effects are due to the require-ment of 4 jets above some pT threshold, and the

generated asymmetry varies from 8% to 3% as a function of the fourth-highest particle jetpT [8]. To

facili-tate comparison with theory, the analysis is therefore de-signed to have an acceptance which can be described simply. Event selection is limited to either (i) selections

on directions and momenta that can be described at the particle level (which refers to produced particles before they interact with material in the detector) or (ii) criteria with high signal efficiency, so that their impact on the region of acceptance is negligible. In addition, the observ-able quantity and the fitting procedure are chosen to ensure that all events have the same weight in determining the asymmetry.

The measurement is not corrected for acceptance and reconstruction effects, but a prescription provides the ac-ceptance at the particle level. Reconstruction effects are also accommodated at the particle level by defining the asymmetry as a function of the generatedjyj:

Afbjyj gjyj gjyj

gjyj gjyj; (1)

wheregis the probability density forywithin the accep-tance. This asymmetry can be folded with the ‘‘geometric dilution’’D, which is described later:

Apredfb Z1

0

AfbyDy gy gydy: (2)

This procedure yields the predictions in TableI. The values are smaller than those of Refs. [1,2], because of the in-clusion of jet acceptance and dilution.

We select events with at least four jets reconstructed using a cone algorithm [9] with an angular radiusR0:5 (in rapidity and azimuthal angle). All jets must havepT>

20 GeV and pseudorapidity (relative to the reconstructed

primary vertex)jj<2:5. The leading jet must havepT>

35 GeV. Events are required to have E6 T>15 GeV and

exactly one isolated electron withpT>15 GeVandjj<

1:1or one isolated muon withpT >18 GeVandjj<2:0. More details on lepton identification and trigger require-ments are given in Ref. [10]. Events in which the lepton momentum is mismeasured are suppressed by requiring that the direction of the E6 T not be along or opposite the azimuth of the lepton. To enhance the signal, at least one of the jets is required to be identified as originating from a long-lived b hadron by a b-jet tagging algorithm [11] which relies on the presence and characteristics of a

sec-TABLE I. Detector level predictions based onMC@NLO.

Njet A

pred fb (in %)

4 0:80:2stat 1:0accept 0:0dilution

[image:4.612.315.562.656.715.2]
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ondary vertex and tracks with high impact parameter inside the jet.

The top-quark pair is reconstructed using a kinematic fitter [12], which varies the four-momenta of the detected objects within their resolutions and minimizes a2

statis-tic, constraining bothWboson masses to exactly 80.4 GeV and top quark masses to exactly 170 GeV. Theb-tagged jet of highestpTand the three remaining jets with highestpT

are used in the fit. The b-tagging information is used to reduce the number of jet-parton assignments considered in the fit. Only events in which the kinematic fit converges are used, and for each event only the reconstruction with the lowest2 is retained.

The selection criteria can be approximated by simple cuts on particle-level momenta without changing the gen-erated asymmetry by more than 2% (absolute). This is verified using several simulated samples with generated asymmetries and particle jets clustered using the PXCONE algorithm [13] (‘‘E’’ scheme and R0:5). The particle jet cuts are pT>21 GeV and jj<2:5, with the

addi-tional requirement on the leading particle jetpT >35 GeV

and the lepton requirements detailed above. Systematic uncertainties on jet energy calibration introduce possible shifts of the particle jet thresholds. The shifts are11::35 GeV for the leading jet and1:2

1:3 GeVfor the other jets, for1

standard deviation (sd) changes in the jet energy calibra-tion. The resulting changes in the asymmetry predicted usingMC@NLOare of the order of 0.5%. The effect of all other selections on the asymmetry is negligible. The pre-dictions in TableIuse a more complete description of the acceptance based on efficiencies factorized inpT and , accurate to<1%(absolute).

Misreconstructing the sign ofydilutes the asymmetry. Such dilution can arise from misidentifying lepton charge or from misreconstructing event geometry. The rate for misidentification of lepton charge is taken from the signal simulation and verified using leptonic Zboson decays in data. False production asymmetries arising from asymme-tries in the rate for misidentification of lepton charge are negligible owing to the frequent reversal of the D0 solenoid and toroid polarities.

The dilutionDdepends mainly onjyj. It is defined as

D2P1, wherePis the probability of reconstructing

the correct sign of y. It is obtained from ttX events generated withPYTHIA[14] and passed through aGEANT -based simulation [15] of the D0 detector, and is parame-trized as

Djyj c0ln1c1jyj c2jyj2; (3)

with the parameters given in TableII[8].

As this measurement is integrated injyj, the depen-dence of the dilution on jyjintroduces a model depen-dence into any correction from observed asymmetry (Aobs

fb )

to a particle-level asymmetry. Such a correction factor would depend not only on the model’sjyjdistribution,

but also on its prediction ofAfbjyj. Furthermore, such a correction would be sensitive to small new physics com-ponents of the selected sample. We therefore present a measurement uncorrected for reconstruction effects and provide the reader with a parametrization of D that de-scribes these effects, to be applied to any model.

The dilution depends weakly on other variables corre-lated with Afb, such as the number of jets. This possible

bias is included in the systematic uncertainties. Nonstandard production mechanisms can affect recon-struction quality, primarily due to changes in the momenta of the top quarks. By studying extreme cases, we find that when comparing nonstandardttXproduction to data an additional 15% relative uncertainty onAfb is needed.

The main background is fromWjets production. To estimate it, we define a likelihood discriminant L using variables that are well described in our simulation, provide separation between signal and Wjets background, and do not biasjyjfor the selected signal. Discrimination is based mainly on thepT of the leadingb-tagged jet and the

2 statistic from the kinematic fit.

[image:5.612.315.561.74.209.2] [image:5.612.314.561.631.716.2]

The next largest background after Wjets is from multijet production, where a jet mimics an isolated elec-tron or muon. Following the procedure described in Ref. [10], the distributions in likelihood discriminant and reconstructed asymmetry for this background are derived from samples of data that fail lepton identification. The normalization of this background is estimated from the size of those samples and the large difference in efficiencies of lepton identification for true and false leptons. The effects of additional background sources not considered explicitly

TABLE II. Parameters of the dilution. The 1sd values in-clude both statistical and systematic uncertainties.

Variation c0 c1 c2

Njet4 0.262 14.6 1:5

1sdvariation 0.229 20.3 1.2

1sdvariation 0.289 11.4 2:2

Njet4 0.251 17.6 1:4

1sdvariation 0.201 30.3 7.7

1sdvariation 0.293 11.6 2:3

Njet5 0.254 9.6 0

1sdvariation 0.206 17.4 2.4

1sdvariation 0.358 5.0 0:9

TABLE III. Number of selected events and fit results in data.

4Jets 4 Jets 5Jets

No. Events 376 308 68

ttX 26623

22 21420 54

10

12

Wjets 7021 611918 7

11

5

Multijets 404 32:73:5

3:3 7:1

1:6

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in extracting Afb, namely Zjets, single top quark, and

diboson production, are evaluated using ensembles of si-mulated data sets and found negligible.

The sample composition and Afb are extracted from a

simultaneous maximum-likelihood fit to data of a sum of contributions toLand to the sign of the reconstructedy

(yreco) from forward signal, backward signal, Wjets, and multijet production. Both signal contributions are gen-erated withPYTHIA, have the same distribution inL, and differ only in their being reconstructed as either forward or backward. The Wjets contribution is generated with ALPGEN[16] interfaced toPYTHIAand has its own recon-structed asymmetry. AlthoughW boson production is in-herently asymmetric, the kinematic reconstruction to the

ttX hypothesis reduces its reconstructed asymmetry to

4:41:6stat%. The multijet contribution is derived

from data, as described above. The fitted parameters are shown in Table III. Correlations between the asymmetry and the other parameters are<10%. In Fig.1we compare the fitted distributions to data for events with4jets.

The dominant sources of systematic uncertainty for the measured asymmetry are the relative jet energy calibration between data and simulation (0:5%), the asymmetry reconstructed inWjets events (0:4%), and the mod-eling of additional interactions during a singlepp bunch crossing (0:4%). The total systematic uncertainty for the asymmetry is1%, which is negligible compared with the statistical uncertainty.

We check the simulation of the production asymmetry, and of the asymmetry reconstructed under the ttX hy-pothesis in the Wjets background, by repeating the analysis in a sample enriched in Wjets events. The selection criteria for this sample are identical to the main analysis, except that we veto on any b tags. Both the reconstructed Afb, 25stat%, and the forward-backward lepton asymmetry, 135stat%, are consis-tent with expectations ( 3:71:5stat% and 11:6

1:5stat%, respectively).

To demonstrate the measurement’s sensitivity to new physics, we examine ttproduction via neutral gauge bo-sons (Z0) that are heavy enough to decay to on-shell top and antitop quarks. Direct searches have placed limits on tt production via a heavy narrow resonance [17], while the asymmetry inttproduction may be sensitive to production via both narrow and wide resonances. TheZ0!ttchannel is of interest in models with a ‘‘leptophobic’’Z0that decays dominantly to quarks. We study the scenario where the coupling between theZ0boson and quarks is proportional to that between the Zboson and quarks, and interference effects with SMttproduction are negligible. UsingPYTHIA we simulate tt production via Z0 resonances with decay rates chosen to yield narrow resonances as in Ref. [17], and find large positive asymmetries [13–35%], which are a consequence of the predominantly left-handed decays. We predict the distribution ofAfbas a function of the fraction

(f) ofttevents produced via aZ0resonance of a particular mass from ensembles of simulated data sets. We use the procedure of Ref. [18] to arrive at the 95% C.L. limits shown in Fig.2. The expected limits, and their variations 1 and 2 standard deviations away due to statistical

fluctua-Z’ mass [GeV]

400 500 600 700 800 900 1000

upper limit on f

0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1 excluded region

D0, 0.9 fb-1

FIG. 2 (color online). Limits onfas a function of theZ0mass. Solid curve and hatching for the observed limits and the ex-cluded region, dashed curve and shaded bands for the expected limits and their statistical variations.

0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

Events/0.025 0 2 4 6 8 10 12 14 16 18 20 0 2 4 6 8 10 12 14 16 18 20

20 Top pairs ± 149 11 W+jets ± 36 3 Multijet ± 21 206 Data

D0, 0.9 fb-1 (a)

Events/0.025 0 2 4 6 8 10 12 14 16 18 20

0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

0 2 4 6 8 10 12 14 16 18 20

20 Top pairs ± 118 10 W+jets ± 33 3 Multijet ± 19 170 Data

D0, 0.9 fb-1 (b)

[image:6.612.62.558.53.210.2] [image:6.612.333.542.538.665.2]
(7)

tions, are determined from ensembles with noZ0 contribu-tion. These limits can be applied to wideZ0resonances by averaging over the distribution ofZ0mass.

In summary, we present the first measurement of the integrated forward-backward charge asymmetry inttX

production. We find that acceptance affects the asymmetry and must be specified as above, and that corrections for reconstruction effects are too model dependent to be of use. We observe an uncorrected asymmetry of Aobs

fb 12

8stat 1syst%forttXevents with4jets that are

within our acceptance, and we provide a dilution function [Eq. (3)] that can be applied to any model [through Eq. (2)]. For events with only four jets and for those with5jets, we find Aobs

fb 199stat 2syst% and Aobsfb

1615

17stat 3syst%, respectively, where most of

the systematic uncertainty is from migrations of events between the two subsamples. The measured asymmetries are consistent with the MC@NLO predictions for SM production.

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); CAPES, 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); Science and Technology Facilities Council (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); Alexander von Humboldt Foundation; and the Marie Curie Program.

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

Visitor from The University of Liverpool, Liverpool, UK.Deceased.

x

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

kVisitor from ICN-UNAM, Mexico City, Mexico.

{Visitor from Helsinki Institute of Physics, Helsinki,

Finland.

**Visitor from Universita¨t Zu¨rich, Zu¨rich, Switzerland. [1] J. H. Ku¨hn and G. Rodrigo, Phys. Rev. D 59, 054017

(1999).

[2] M. T. Bowen, S. D. Ellis, and D. Rainwater, Phys. Rev. D

73, 014008 (2006).

[3] S. Dittmaier P. Uwer, and S. Weinzierl, Phys. Rev. Lett.

98, 262002 (2007).

[4] For example, O. Antun˜ano, J. H. Ku¨hn, and G. Rodrigo, Phys. Rev. D77, 014003 (2008).

[5] Rapidityyand pseudorapidityare defined as functions of the polar angleasy; 1

2ln 1cos=1 cos; y;1, where is the ratio of a particle’s momentum to its energy.

[6] V. M. Abazov et al. (D0 Collaboration), Nucl. Instrum. Methods Phys. Res., Sect. A565, 463 (2006).

[7] S. Frixione and B. R. Webber, J. High Energy Phys. 06 (2002) 29;S. Frixioneet al.,ibid.08 (2003) 7.

[8] See EPAPS Document No. E-PRLTAO-100-059814 for additional plots. For more information on EPAPS, see http://www.aip.org/pubservs/epaps.html.

[9] G. C. Blazeyet al., inProceedings of the Workshop: QCD and Weak Boson Physics in Run II, edited by U. Baur, R. K. Ellis, and D. Zeppenfeld (Fermilab Report No. Fermilab-Pub-00/297, 2000).

[10] V. M. Abazovet al.(D0 Collaboration), Phys. Rev. D76, 092007 (2007).

[11] T. Scanlon, Ph.D. thesis, University of London (Fermilab Report No. Fermilab-Thesis-2006-43, 2006).

[12] S. Snyder, Ph.D. thesis, State University of New York at Stony Brook, 1995.

[13] C. Adloffet al.(H1 Collaboration), Nucl. Phys.B545, 3 (1999).

[14] T. Sjo¨strand et al., Comput. Phys. Commun. 135, 238 (2001).

[15] R. Brun and F. Carminati, CERN Program Library Long Writeup Report No. W5013, 1993 (unpublished). [16] M. L. Manganoet al., J. High Energy Phys. 07 (2003) 1; S.

Ho¨cheet al., arXiv:hep-ph/0602031.

[17] V. M. Abazovet al.(D0 Collaboration), Phys. Rev. Lett.

92, 221801 (2004); T. Aaltonen et al. (CDF Collaboration), arXiv:0709.0705.

Figure

TABLE I.Detector level predictions based on MC@NLO.
TABLE II.Parameters of the dilution. The �1 sd values in-clude both statistical and systematic uncertainties.
FIG. 1 (color online).Comparison of data for � 4 jets with the fitted model as a function of L for events reconstructed (a) as forward(�yreco > 0) and (b) as backward (�yreco < 0)

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