Uma nova assinatura para glueballs

A representação de Fock-Tani é um formalismo de teoria de campos para tratar problemas envolvendo simultaneamente partículas compostas e seus constituintes. O formalismo foi originalmente desenvolvido para tratar problemas de física atômica e mais tarde estendido para problemas da física hadrônica. Nesta dissertação, inicialmente apresentamos uma revisão da Cromo dinâmica Quântica e dos modelos de quarks e de glúons constituintes. Revisamos também a representação de Fock-Tani para mésons e buscamos estendê-Ia para estados exóticos, mais precisamente para glueballs. Neste formalismo uma mudança de representação é implementada através de um operador unitário, tal que estados de glueballs no espaço de Fock, compostos por um par glúon-glúon, sejam descritos em termos de operadores de campo de glueballs elementares em um espaço de Hilbert estendido. A aplicação do operador unitário a um Hamiltoniano microscópico de gluons leva a um Hamiltoniano efetivo que descreve todos os possíveis processos envolvendo glúons e glueballs. Esse Hamiltoniano efetivo é utilizado para estudar as interações entre glueballs à baixa energia em um modelo de glúons constituintes, que interagem através da troca de um glúon virtual e são confinados por um potencial fenomenológico O méson J?C = 0++ pode ser descrito de duas formas completamente diferentes. Na primeira forma ele é descrito da maneira usual como sendo composto por um par qq. Na segunda abordagem este mesmo méson é descrito como sendo constituido por dois glúons (glueball). Também estudamos nesta dissertação o méson 2++ no mesmo contexto. Os resultados obtidos nesta dissertação indicam que o méson qq precisaria ter um raio quase igual ao dobro do respectivo raio do glueball para que suas seções de choque de espalhamento elástico fossem equivalentes. As diferenças acentuadas encontradas nas seções de choque de espalhamento elástico méson-méson e glueball-glueball, podem ser interpretadas como uma nova assinatura de glueballs.

QCD vacuum topology and glueballs

We outline a comprehensive study of spin-0 glueball properties which, in particular, keeps track of the topological gluon structure. Specifically, we implement (semi-hard) topological instanton physics as well as topological charge screening in the QCD vacuum into the operator product expansion (OPE) of the glueball correlators. A realistic instanton size distribution and the (gauge-invariant) renormalization of the instanton contributions are also implemented. Predictions for 0(++) and 0(-+) glueball properties are presented.

Topological charge screening and pseudoscalar glueballs

Topological charge screening in the QCD vacuum is found to provide crucial nonperturbative contributions to the short-distance expansion of the pseudoscalar (0-+) glueball correlator. The screening contributions enter the Wilson coefficients and are an indispensable complement to the direct instanton contributions. They restore consistency with the anomalous axial Ward identity and remedy several flaws in the 0-+ glueball sum rules caused by direct instantons in the absence of screening (lack of resonance signals, violation of the positivity bound and of the underlying low-energy theorem). The impact of the finite width of the instanton size distribution and the (gauge-invariant) renormalization of the instanton contributions are also discussed. New predictions for the 0-+ glueball mass and decay constant are presented.

Glueballs as intermediate states in hadronic transitions

Hadronic transitions rates in the heavy quarkonium systems are calculated within the framework of the QCD multipole expansion. The spectrum of glueballs consisting of two massive gluons, obtained by the use of the potential model, is adopted as a suitable description of the intermediate states. Comparisons with the quark confining string model (QCS) and the bag model are made. © 1990 Springer-Verlag.

Glueballs in peripheral heavy-ion collisions

We estimate the cross-section for glueball production in peripheral heavy-ion collisions through two-photon and double-Pomeron exchange, at energies that will be available at RHIC and LHC. Glueballs will be produced at large rates, opening the possibility to study decays with very small branching ratios. In particular, we discuss the possibility of observing the subprocess γγ(PP) → G → γγ.

Mass spectra of glueballs and hybrids

Assuming massive constituent gluons the mass spectroscopy of glueballs and hybrids is analysed in the framework of the potential model. Only pairwise potentials are considered.

Natural classification of knots

The principal objective of the knot theory is to provide a simple way of classifying and ordering all the knot types. Here, we propose a natural classification of knots based on their intrinsic position in the knot space that is defined by the set of knots to which a given knot can be converted by individual intersegmental passages. In addition, we characterize various knots using a set of simple quantum numbers that can be determined upon inspection of minimal crossing diagram of a knot. These numbers include: crossing number; average three-dimensional writhe; number of topological domains; and the average relaxation value

Large N QCD from rotating branes

We study large N SU(N) Yang-Mills theory in three and four dimensions using a one-parameter family of supergravity models which originate from non-extremal rotating D-branes. We show explicitly that varying this angular momentum parameter decouples the Kaluza-Klein modes associated with the compact D-brane coordinate, while the mass ratios for ordinary glueballs are quite stable against this variation, and are in good agreement with the latest lattice results. We also compute the topological susceptibility and the gluon condensate as a function of the "angular momentum" parameter.

Infrared degrees of freedom of Yang-Mills theory in the Schrodinger representation

We set up a new calculational framework for the Yang-Mills vacuum transition amplitude in the Schrodinger representation. After integrating out hard-mode contributions perturbatively and performing a gauge-invariant gradient expansion of the ensuing soft-mode action, a manageable saddle-point expansion for the vacuum overlap can be formulated. In combination with the squeezed approximation to the vacuum wave functional this allows for an essentially analytical treatment of physical amplitudes. Moreover, it leads to the identification of dominant and gauge-invariant classes of gauge field orbits which play the role of gluonic infrared (IR) degrees of freedom. The latter emerge as a diverse set of saddle-point solutions and are represented by unitary matrix fields. We discuss their scale stability, the associated virial theorem and other general properties including topological quantum numbers and action bounds. We then find important saddle-point solutions (most of them solitons) explicitly and examine their physical impact. While some are related to tunneling solutions of the classical Yang-Mills equation, i.e. to instantons and merons, others appear to play unprecedented roles. A remarkable new class of IR degrees of freedom consists of Faddeev-Niemi type link and knot solutions, potentially related to glueballs.

O modelo de Skyrme-Faddeev para o SU(N)

Pós-graduação em Física - IFT