330 research outputs found
Effective potential in the BET formalism
We calculate the one-loop effective potential at finite temperature for a
system of massless scalar fields with quartic interaction in
the framework of the boundary effective theory (BET) formalism. The calculation
relies on the solution of the classical equation of motion for the field, and
Gaussian fluctuations around it. Our result is non-perturbative and differs
from the standard one-loop effective potential for field values larger than
.Comment: 10 pages, 3 figure
Non-perturbative computation of double inclusive gluon production in the Glasma
The near-side ridge observed in A+A collisions at RHIC has been described as
arising from the radial flow of Glasma flux tubes formed at very early times in
the collisions. We investigate the viability of this scenario by performing a
non-perturbative numerical computation of double inclusive gluon production in
the Glasma. Our results support the conjecture that the range of transverse
color screening of correlations determining the size of the flux tubes is a
semi-hard scale, albeit with non-trivial structure. We discuss our results in
the context of ridge correlations in the RHIC heavy ion experiments.Comment: 25 pages, 11 figures, uses JHEP3.cls V2: small clarifications,
published in JHE
Viscosity and the Soft Ridge at RHIC
Correlation studies exhibit a ridge-like feature in rapidity and azimuthal
angle, with and without a jet trigger. We ask whether the feature in
untriggered correlations can be a consequence of transverse flow and viscous
diffusion.Comment: Proc. Quark Matter 2008, Jaipur, Indi
Lattice worldline representation of correlators in a background field
We use a discrete worldline representation in order to study the continuum
limit of the one-loop expectation value of dimension two and four local
operators in a background field. We illustrate this technique in the case of a
scalar field coupled to a non-Abelian background gauge field. The first two
coefficients of the expansion in powers of the lattice spacing can be expressed
as sums over random walks on a d-dimensional cubic lattice. Using combinatorial
identities for the distribution of the areas of closed random walks on a
lattice, these coefficients can be turned into simple integrals. Our results
are valid for an anisotropic lattice, with arbitrary lattice spacings in each
direction.Comment: 54 pages, 14 figure
Exploring Early Parton Momentum Distribution with the Ridge from the Near-Side Jet
In a central nucleus-nucleus collision at high-energies, medium partons
kicked by a near-side jet acquire a momentum along the jet direction and
subsequently materialize as the observed ridge particles. They carry direct
information on the early parton momentum distribution which can be extracted by
using the ridge data for central AuAu collisions at \sqrt{s_{NN}}=200 GeV. The
extracted parton momentum distribution has a thermal-like transverse momentum
distribution but a non-Gaussian, relatively flat rapidity distribution at
mid-rapidity with sharp kinematic boundaries at large rapidities that depend on
the transverse momentum.Comment: In Proceedings of 20th International Conference on Ultra-Relativistic
Nucleus Nucleus Collisions, Jaipur, India, Feb. 4-10, 200
KLN theorem, magnetic mass, and thermal photon production
We study the infrared singularities associated to ultra-soft transverse
gluons in the calculation of photon production by a quark-gluon plasma. Despite
the fact that the KLN theorem works in this context and provides cancellations
of infrared singularities, it does not prevent the production rate of low
invariant mass dileptons to be sensitive to the magnetic mass of gluons and
therefore the rate to be non perturbative.Comment: 9 pages Latex document, 5 postscript figures, modified figure 5 and
slightly updated section
Long range correlations, event simulation and parton percolation
We study the RHIC data on long range rapidity correlations, comparing their
main trends with different string model simulations. Particular attention is
paid to color percolation model and its similarities with color glass
condensate. As both approaches corresponds, at high density, to a similar
physical picture, both of them give rise to a similar behavior on the energy
and the centrality of the main observables. Color percolation explains the
transition from low density to high density.Comment: Contribution to the meeting : Saturation, the CGC and the Glasma BNL.
May 10-12, accepted in Nuclear Physics
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