501 research outputs found
Hydrodynamic Models for Heavy Ion Collisions
Application of hydrodynamics for modeling of heavy-ion collisions is
reviewed. We consider several physical observables that can be calculated in
this approach and compare them to the experimental measurements.Comment: 42 pages, 15 figures, An invited review for Nov. 2006 edition of
Annual Review of Nuclear and Particle Physic
Hadron multiplicities, pT-spectra and net-baryon number in central Pb+Pb collisions at the LHC
We compute the initial energy density and net baryon number density in 5%
most central Pb+Pb collisions at TeV from pQCD + (final state)
saturation, and describe the evolution of the produced system with
boost-invariant transversely expanding hydrodynamics. In addition to the total
multiplicity at midrapidity, we give predictions for the multiplicity of
charged hadrons, pions, kaons and (anti)protons, for the total transverse
energy and net-baryon number, as well as for the -spectrum of charged
hadrons, pions and kaons. We also predict the region of applicability of
hydrodynamics by comparing these results with high- hadron spectra
computed from pQCD and energy losses.Comment: 2 pages, 2 figures, to be presented at the workshop "Heavy Ion
Collisions at the LHC: Last Call for Predictions" at CERN 29 May - 2 Jun
Transverse Spectra of Hadrons in Central Collisions at RHIC and LHC from pQCD+Saturation+Hydrodynamics and from pQCD+Energy Losses
We study the transverse spectra of hadrons in nearly central collisions
at RHIC and LHC in a broad transverse momentum range Low- spectra are
calculated by using boost-invariant hydrodynamics with initial energy and
net-baryon densities from the EKRT pQCD+saturation model. High- spectra
are obtained from pQCD jet calculation including the energy loss of the parton
in the matter prior to its fragmentation to final hadrons.Comment: 4 pages, 2 figures, proceedings for Quark Matter 200
Photon HBT interferometry for non-central heavy-ion collisions
Currently, the only known way to obtain experimental information about the
space-time structure of a heavy-ion collision is through 2-particle momentum
correlations. Azimuthally sensitive HBT interferometry (Hanbury Brown-Twiss
intensity interferometry) can complement elliptic flow measurements by
constraining the spatial deformation of the source and its time evolution.
Performing these measurements on photons allows us to access the fireball
evolution at earlier times than with hadrons. Using ideal hydrodynamics to
model the space-time evolution of the collision fireball, we explore
theoretically various aspects of 2-photon intensity interferometry with
transverse momenta up to 2 GeV, in particular the azimuthal angle dependence of
the HBT radii in non-central collisions. We highlight the dual nature of
thermal photon emission, in both central and non-central collisions, resulting
from the superposition of QGP and hadron resonance gas photon production. This
signature is present in both the thermal photon source function and the HBT
radii extracted from Gaussian fits of the 2-photon correlation function.Comment: 18 pages, 12 figure
Which probes are most useful when undertaking cognitive interviews?
This paper reports the use of verbal probes in cognitive interviews (CIs) undertaken to test the usefulness, validity and reliability of survey questions. Through examining the use of probes by three interviewers undertaking interviews as part the piloting of a cross-national crime survey, we examine which of the various types of probes used in CIs produce the most useful information. Other influences on interview quality are examined, including differences between interviewers and respondents themselves. The analyses rely on multi-level modelling and suggest that anticipated, emergent and conditional probes provide the most useful data. Furthermore, age, gender and educational levels appear to have no bearing on the quality of the data generated
RHIC-tested predictions for low- and high- hadron spectra in nearly central Pb+Pb collisions at the LHC
We study the hadron spectra in nearly central + collisions at RHIC and
LHC in a broad transverse momentum range. We cover the low- spectra using
longitudinally boost-invariant hydrodynamics with initial energy and net-baryon
number densities from the perturbative QCD (pQCD)+saturation model. Build-up of
the transverse flow and sensitivity of the spectra to a single decoupling
temperature \Tdec are studied. Comparison with RHIC data at \ssNN=130 and
200 GeV suggests a rather high value \Tdec=150 MeV. The high- spectra
are computed using factorized pQCD cross sections, nuclear parton
distributions, fragmentation functions, and describing partonic energy loss in
the quark-gluon plasma by quenching weights. Overall normalization is fixed on
the basis of p+(p) data and the strength of energy loss is
determined from RHIC Au+Au data. Uncertainties are discussed. With constraints
from RHIC data, we predict the spectra of hadrons in 5 % most central
Pb+Pb collisions at the LHC energy \ssNN=5500 GeV. Due to the closed
framework for primary production, we can also predict the net-baryon number at
midrapidity, as well as the strength of partonic energy losses at the LHC. Both
at the LHC and RHIC, we recognize a rather narrow crossover region in the
spectra, where the hydrodynamic and pQCD fragmentation components become of
equal size. We argue that in this crossover region the two contributions are to
a good approximation mutually independent. In particular, our results suggest a
wider -region of applicability for hydrodynamical models at the LHC than
at RHIC.Comment: 45 pages, 16 eps-figure
PRODUCTION OF DRELL--YAN PAIRS IN HIGH ENERGY NUCLEON--NUCLEON COLLISIONS
We compute cross sections for the Drell-Yan process in N--N collisions at
next-to-leading order in . The mass, rapidity, transverse momentum,
and angular dependence of these cross sections are presented. An estimate of
higher order corrections is obtained from next-to-next-to-leading order
calculation of the mass distribution. We compare the results with some of the
existing data to show the quality of the agreement between calculations and
data. We present predictions for energies which will become available at the
RHIC and LHC colliders. Uncertainties in these predictions due to choices of
scale, scheme and parton distribution are discussed.Comment: 27 pages (latex) plus 28 postscript figure
Heavy Ion Physics at the LHC with the ATLAS Detector
The ATLAS detector at CERN will provide a high-resolution
longitudinally-segmented calorimeter and precision tracking for the upcoming
study of heavy ion collisions at the LHC (sqrt(s_NN)=5520 GeV). The calorimeter
covers |eta|<5 with both electromagnetic and hadronic sections, while the inner
detector spectrometer covers |eta|<2.5. ATLAS will study a full range of
observables necessary to characterize the hot and dense matter formed at the
LHC. Global measurements (particle multiplicities, collective flow) will
provide access into its thermodynamic and hydrodynamic properties. Measuring
complete jets out to 100's of GeV will allow detailed studies of energy loss
and its effect on jets. Quarkonia will provide a handle on deconfinement
mechanisms. ATLAS will also study the structure of the nucleon and nucleus
using forward physics probes and ultraperipheral collisions, both enabled by
segmented Zero Degree Calorimeters.Comment: 9 pages, 8 figures, submitted to the Proceedings of Quark Matter
2006, Shanghai, China, November 14-20, 200
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