Heavy Vector Research Articles

Search for WZ resonances in the fully leptonic channel using pp collisions at [formula omitted] with the ATLAS detector

A search for resonant WZ production in the ℓνℓ′ℓ′ (ℓ,ℓ′=e,μ) decay channel using 20.3 fb−1 of s=8 TeVpp collision data collected by the ATLAS experiment at LHC is presented. No significant deviation from the Standard Model prediction is observed and upper limits on the production cross sections of WZ resonances from an extended gauge model W′ and from a simplified model of heavy vector triplets are derived. A corresponding observed (expected) lower mass limit of 1.52 (1.49) TeV is derived for the W′ at the 95% confidence level.

Analysis of three-body B decays to heavy vector and light pseudoscalar mesons

In this research, we analysis the three-body decays of the B0 meson to and final-state mesons. By taking the factorization approach, for these decay modes, color-suppressed internal W-emission and penguin Feynman diagrams can be plotted. The transition matrix elements of are factorized into a form factor multiplied by the decay constant. We investigate these decays by using the Dalitz plot analysis with an important assumption. We assume that, in the decays, because the mass of the is too heavy against the K and π mesons, therefore it carries a small momentum. In particular, the backlash of the can be neglected. With this assumption we get that the meson remains stationary, and the K and π mesons move back to back. We calculate the nonresonant contribution of and decays and the branching ratios become and , respectively, and the experimental results for them are and , respectively. Note that the resonant contributions are very small, so we ignore them in our calculations.

Review of single vector boson production in pp collisions at $$\sqrt{s} = 7$$ s = 7 TeV

This review summarises the main results on the production of single vector bosons in the Standard Model, both inclusively and in association with light and heavy flavour jets, at the Large Hadron Collider in proton-proton collisions at a center-of-mass energy of 7 TeV. The general purpose detectors at this collider, ATLAS and CMS, each recorded an integrated luminosity of $\approx 40\,{\rm pb^{-1}}$ and $5\,{\rm fb^{-1}}$ in the years 2010 and 2011, respectively. The corresponding data offer the unique possibility to precisely study the properties of the production of heavy vector bosons in a new energy regime. The accurate understanding of the Standard Model is not only crucial for searches of unknown particles and phenomena but also to test predictions of perturbative Quantum-Chromo-Dynamics calculations and for precision measurements of observables in the electroweak sector. Results from a variety of measurements in which single W or Z bosons are identified are reviewed. Special emphasis in this review is given to interpretations of the experimental results in the context of state-of-the-art predictions.

Maximal unitarity for the four-mass double box

We extend the maximal-unitarity formalism at two loops to double-box integrals with four massive external legs. These are relevant for higher-point processes, as well as for heavy vector rescattering, VV -> VV. In this formalism, the two-loop amplitude is expanded over a basis of integrals. We obtain formulas for the coefficients of the double-box integrals, expressing them as products of tree-level amplitudes integrated over specific complex multidimensional contours. The contours are subject to the consistency condition that integrals over them annihilate any integrand whose integral over real Minkowski space vanishes. These include integrals over parity-odd integrands and total derivatives arising from integration-by-parts (IBP) identities. We find that, unlike the zero- through three-mass cases, the IBP identities impose no constraints on the contours in the four-mass case. We also discuss the algebraic varieties connected with various double-box integrals, and show how discrete symmetries of these varieties largely determine the constraints.

Prediction of a Zc(4000) $$D^* \bar D^*$$ state and relationship with the claimed Zc(4025)

After discussing the OZI suppression of one light meson exchange in the interaction of $D^* \bar D^*$ with isospin I=1, we study the contribution of two pion exchange to the interaction and the exchange of a heavy vector $J/\psi$. We find this latter mechanism weak but enough to barely bind the system in J=2 with a mass around 4000 MeV, while the effect of the two pion exchange is a net attraction but weaker than that from $J/\psi$ exchange. We discuss this state and try to relate it to the $Z_c(4025)$ state, above the $D^* \bar D^*$ threshold, claimed in an experiment at BES from and enhancement of the $D^* \bar D^*$ distribution close to threshold. Together with the results from a recent reanalysis of the BES experiment showing that it is compatible with a J=2 state below threshold around 3990 MeV, we conclude that the BES experiment could be showing the existence of the state that we find in our approach.

ULTRA HIGH-ENERGY NEUTRINOS VIA HEAVY-MESON SYNCHROTRON EMISSION IN STRONG MAGNETIC FIELDS

We explore the generation and possibility for the detection of heavy-meson synchrotron emission due to the acceleration of ultra-relativistic protons (and possibly nuclei) in the presence of strong magnetic fields (H 1015?G) in transient astrophysical environments such as magnetar flares. We show that, in addition to the well-known pion synchrotron emission, heavy vector mesons like ?, DS , J/?, and could be generated. For high enough energies and magnetic field strengths, such heavy vector mesons can be formed with high intensity (~103 times the photon intensity) through strong couplings to the ultra-relativistic nucleons. We examine in particular the synchrotron emission and subsequent cooling and decay of the heavy ?0 and (1S) mesons, e.g., via p ? p' + (1S), (1S) ? ?+ + ??, and . We evaluate the spectra of escaping ? e , ??, and ?? due to the decay of short-lived ? mesons. We deduce the possible event rate in a terrestrial TeV neutrino detector. We estimate that neutrinos produced from the heavy vector-meson synchrotron radiation from a strong magnetar soft gamma repeater burst will only be detectable with the current generation of detectors if the source is very nearby (<30 pc). Nevertheless, if ever detected, the existence of heavy meson synchrotron emission might be identifiable by the unique signature of energetic tau neutrinos emanating from the source.

CHARMING BARYONS

We study odd-parity baryonic resonances with one heavy and three light flavors, dynamically generated by meson-baryon interactions. Special attention is paid to Heavy Quark Spin Symmetry (HQSS), hence pseudoscalar and vector mesons and baryons with Jπ = 1/2+ and 3/2+ are considered as constituent hadrons. For the hidden-charm sector ([Formula: see text]), the meson-baryon Lagrangian with Heavy Flavor Symmetry is constructed by a minimal extension of the SU(3) Weinberg-Tomozawa (WT) Lagrangian to fulfill HQSS, such that not new parameters are needed. This interaction can be presented in different formal ways: as a Field Lagrangian, as Hadron creation-annihilation operators, as SU(6)×HQSS group projectors and as multichannel matrices. The multichannel Bethe-Salpeter equation is solved for odd-parity light baryons, hidden-charm N and Δ and Beauty Baryons (Λb). Results of calculations with this model are shown in comparison with other models and experimental values for baryonic resonances.

Hadron form factors and large-Ncphenomenology

The half width rule provides a way to consider 1/Nc corrections to hadronic models containing resonances. Consequences of such ideas for hadron form factors and Regge trajectories are explored, with special emphasis on the possibility to describe the spectrum of light and heavy unflavored vector mesons in a universal way.

Heavy Scalar, Vector, and Axial-Vector Mesons in Hot and Dense Nuclear Medium

In this work we shall investigate the mass modifications of scalar mesons (D0;B0), vector mesons (D*;B*), and axial-vector mesons (D1;B1) at finite density and temperature of the nuclear medium. The above mesons are modified in the nuclear medium through the modification of quark and gluon condensates. We will find the medium modification of quark and gluon condensates within chiral SU(3) model through the medium modification of scalar-isoscalar fieldsσandζat finite density and temperature. These medium modified quark and gluon condensates will further be used through QCD sum rules for the evaluation of in-medium properties of the above mentioned scalar, vector, and axial vector mesons. We will also discuss the effects of density and temperature of the nuclear medium on the scattering lengths of the above scalar, vector, and axial-vector mesons. The study of the medium modifications of the above mesons may be helpful for understanding their production rates in heavy-ion collision experiments. The results of present investigations of medium modifications of scalar, vector, and axial-vector mesons at finite density and temperature can be verified in the compressed baryonic matter (CBM) experiment of FAIR facility at GSI, Germany.

Dark matter thermalization in neutron stars

We study how many-body effects alter the dark matter (DM) thermalization time inside neutron stars. We find that Pauli blocking, kinematic constraints, and superfluidity and superconductivity in the neutron star significantly affect the DM thermalization time, in general lengthening it. This could change the final DM mass and DM-nucleon cross section constraints by considering black hole formation in neutron stars due to DM accretion. We consider the class of models in which DM is an asymmetric, complex scalar particle with a mass between 1 keV and 5 GeV which couples to regular matter via some heavy vector boson. Interestingly, we find that the discovery of asymmetric, bosonic DM could motivate the existence of exotic neutron star cores. We apply our results to the case of mixed sneutrino DM.

Quarkonia RdAu and FVTX c/b measurement at the PHENIX

Since quarkonia are produced dominantly by gluon-gluon fusion process, it is a good channel to explore the gluon distribution of the nucleon and its modification in nuclei. Contrasting with heavy ion collisions, d + A collisions are not expected to create a hot medium of nuclear matter. Therefore, we can study the quarkonia production in d + A collision and separate the cold nuclear matter effects from the pattern seen in the collisions of large nuclei. The PHENIX collaboration has measured interesting results for J/ψ, ψ' and χc at mid rapidity, |η| < 0.35, and J/ψ and Υ at forward rapidity, 1.2 < η < 2.2 for = 200 GeV d + Au collisions [1–4]. Recently the Forward Silicon Vertex Detector (FVTX) has been installed to the PHENIX detector and much more precise open heavy flavor and vector meson measurements will be possible in the forward rapidity region of the PHENIX Muon Arms. In this talk we will show the aforementioned quarkonia measurements from PHENIX and report on the status of the FVTX detector and physics analyses that will use the FVTX detector in conjunction with the Muon Arms.

A flavorful top-coloron model

In this paper we introduce a simple renormalizable model of an extended color gauge sector in which the third-generation quarks couple differently than the lighter quarks. In addition to a set of heavy color-octet vector bosons (colorons), the model also contains a set of heavy weak vector quarks. Mixing between the third-generation of quarks and the first two is naturally small, and occurs only through the (suppressed) mixing of all three generations with the heavy vector quarks. We discuss the constraints on this model arising from limits on flavor-changing neutral currents and from collider searches for the colorons and vector quarks, and discuss the prospects for discovery at the LHC.

Quarkonium formation time in quark-gluon plasma

The quarkonium formation time in a quark-gluon plasma (QGP) is determined from the space-time correlator of heavy quark vector currents using the quarkonium in-medium mass and wave function obtained from heavy quark potentials extracted from the lattice QCD. It is found that the formation time of a quarkonium increases with the temperature of the QGP and diverges near its dissociation temperature. Also, the quarkonium formation time is longer if the heavy quark potential is taken to be the free energy from lattice calculations for a heavy quark pair, compared to that based on the more negative internal energy.

Bethe-Salpeter wave functions for the bound states composed of two vector fields of arbitrary spin and their application

The most general form of the Bethe-Salpeter wave functions for the bound states composed of two vector fields of arbitrary spin and definite parity is given. Using the property of vector field ${\ensuremath{\partial}}_{\ensuremath{\mu}}{A}_{\ensuremath{\mu}}(x)=0$, we find that the most general form can be simplified. Then this general form is applied to investigate the bound states composed of two heavy vector mesons and these heavy vector mesons are regarded as resonances. The interaction kernel between two heavy mesons including one light meson $(\ensuremath{\sigma},\ensuremath{\omega},\ensuremath{\rho})$ exchange is considered.

Heavy mesons in the Nambu—Jona-Lasinio model

We propose an extended Nambu—Jona-Lasinio model to include heavy mesons with heavy quark symmetry. The quark current—current interaction is generalized to include the heavy quark currents. In order to comply with the heavy quark spin symmetry at the heavy quark limit, the dependence of the quark mass on the interaction strength is introduced. The light and heavy pseudo-scalar and vector mesons, their masses and the weak decay constants are calculated in the unified frame.

Radiative type-I seesaw model with dark matter viaU(1)B−Lgauge symmetry breaking at future linear colliders

We discuss phenomenology of the radiative seesaw model in which spontaneous breaking of the $\mathrm{U}(1{)}_{\mathrm{B}\ensuremath{-}\mathrm{L}}$ gauge symmetry at the TeV scale gives the common origin for masses of neutrinos and dark matter [S. Kanemura, T. Nabeshima, and H. Sugiyama, Phys. Rev. D 85, 033004 (2012).]. In this model, the stability of dark matter is realized by the global $\mathrm{U}(1{)}_{\mathrm{DM}}$ symmetry which arises by the $\mathrm{B}\ensuremath{-}\mathrm{L}$ charge assignment. Right-handed neutrinos obtain TeV scale Majorana masses at the tree level. Dirac masses of neutrinos are generated via one-loop diagrams. Consequently, tiny neutrino masses are generated at the two-loop level by the seesaw mechanism. This model gives characteristic predictions, such as light decayable right-handed neutrinos, Dirac fermion dark matter, and an extra heavy vector boson. These new particles would be accessible at collider experiments because their masses are at the TeV scale. The $\mathrm{U}(1{)}_{\mathrm{B}\ensuremath{-}\mathrm{L}}$ vector boson may be found at the LHC, while the other new particles could only be tested at future linear colliders. We find that the dark matter can be observed at a linear collider with $\sqrt{s}=500\text{ }\text{ }\mathrm{GeV}$ and that light right-handed neutrinos can also be probed with $\sqrt{s}=1\text{ }\text{ }\mathrm{TeV}$.

Heavy flavor and vector boson associated production

The mechanism of production of heavy-flavoured mesons, containing b or c quarks, in association with vector bosons, W or Z/γ⁎, in the Standard Model is only partially understood. The study of events with one or two well-identified and isolated leptons accompanied by b-jets or secondary vertices is therefore crucial to refine the theoretical calculations in perturbative QCD, as well as validate associated Monte Carlo techniques. The deep understanding of these processes is furthermore required by Higgs and BSM analyses with similar final states. Using the LHC proton-proton collision data collected in 2010 and 2011 at a centre of mass energy of 7 TeV by the CMS detector, preliminary measurements of the Z/γ⁎+b(b) cross sections and angular correlations are presented. Finally, the study of the W+c production rate with respect to the W charge and W+light jets rates allows to probe the strange quark content of the proton. These results are also presented.

Analysis of the Form Factors Present in the Description of Heavy Vector Meson Decay

In recently published work by the author, in which the decay rates of all known $1S$ vector meson states have been explained via the Gluon Emission Model ({\rm GEM}), form factors, $f_{j}$ , come into play as associated with the descriptions of the decays of the $\Psi (1S)$ and the $\Upsilon (1S)$, where, in the case of the $\Psi (1S)$, $f_{1} = 1 - q_{s}^{2}$ $(q_{s}$ represents the charge of the strange $(s)$ quark in units of the electron charge), and, in the case of the $\Upsilon (1S)$, $f_{2} = 1$. Specifically, $f_{j}$ represents the fraction of relevant given vector meson states which make a point-like transition to a quark/anti-quark structure of the next lesser mass \dots charm/anti-charm $(cc^*) $ to strange/anti-strange $(ss^*)$ in the case of the $\Psi (1S)$ and bottom/anti-bottom $(bb^*)$ to $cc^*$ in the case of the $\Upsilon(1S)$ \dots the latter respective structures either forming the major portion of the decay scheme (the $\Psi(1S)$), or its entirety (the $\Upsilon (1S)$). Investigation of $\Psi (NS)$ and $\Upsilon (NS)$ states, with $N>1$, has revealed three highly interesting eventualities: (1)~$f_{1}$ retains its form noted above as associated with all presently known $\Psi (NS)$, while (2)~$f_{2}$ is seen to be unique to the $\Upsilon (1S)$, as for the known $\Upsilon (NS)$ states, the resulting form factor is seen to be $f_{3} = 1 - q_{c}^{2}$, where $q_{c }$ represents the charm quark charge. In addition to the above it appears convincingly that (3) for a respective given ``$N$'' such that $N \ge 2$, quark color disengagement from lepton production takes place. In the work which follows we attempt to represent the above-mentioned form factors in a logically consistent way as stemming from what we term as ``Reduction Operators''. Necessarily, $f_{2}$ is of a slightly different form than that of $f_{1}$ or $f_{3}$; therefore, we posit a logical reason as to the nature of the difference, viz., the $\Upsilon (1S)$ never does find itself as a $bb^*$ construction. Rather, it starts out as and decays as a $cc^*$ construction. In addition, from a detailed look into the situation pertaining to the $\psi (NS)$ decay, we suggest that ``quark color disengagement'' from the decay of the relevant $N \ge 2$ states is consistent what we denote as ``dimensional reduction'', which is seen to involve reflection-invariant arrays of entangled di-quark structures within an assumed cubic lattice arrangement of same. Investigation of the analogous situation pertaining to the $\Upsilon (NS)$ decay suggests, on the other hand, that ``dimensional reduction'' is its own phenomenon. Nevertheless, we attempt to make the case that the two phenomena are intricately tied together.

Combining searches of Z′ and W′ bosons

We study in a model-independent way new neutral and charged vector bosons that could give observable signals with leptonic final states at the LHC. We show, in particular, that a charged vector W′ decaying into lepton plus neutrino is accompanied by at least an extra neutral vector boson Z′, nearly degenerate with the charged one. Conversely, a Z′ boson with significant isospin violation cannot exist without a companion W′. To take advantage of these generic correlations, we perform a combined analysis of LHC data in the dilepton and lepton-plus-missing-energy channels, which allows us to improve the limits from independent analyses. We also develop some tools to easily deal with cases in which several heavy vector bosons with similar masses interfere. Finally, we develop a theoretically consistent framework for the study of the sequential Z′ and W′ benchmarks.

COMPLEX-MASS SCHEME AND PERTURBATIVE UNITARITY

We derive cutting rules for loop integrals containing propagators with complex masses. Using a field-theoretical model of a heavy vector boson interacting with a light fermion, we demonstrate that the complex-mass scheme respects unitarity order by order in a perturbative expansion provided that the renormalized coupling constant remains real.