heavy ion physics with the atlas detector helio takai brookhaven national laboratory [email protected]...

Heavy Ion Physics with the ATLAS detector

Helio TakaiBrookhaven National Laboratory

[email protected]

IV INTERNATIONAL SYMPOSIUM ON LHC PHYSICS AND DETECTORS

Fermilab May 1-3,2003

Helio Takai, BNL, IV International Symposium on LHC Physics and Detectors, Fermilab, May 2003 2

Introduction

Heavy Ion Collisions at the LHC will allow us to study an unique QCD system at the limit of extreme energy densities.

This system will contain tens of thousands of gluons, quarks and antiquarks in a relatively small volume.

RHIC results suggest that hard scattering embedded in the system is one of the best ways to probe the early stages of the matter formed in these collision.

The complexity of heavy ion collision will require the understanding of proton-nucleus and proton-proton collisions preferably in the same detector acceptance.


Nucleus-Nucleus Collision

A central nucleus-nucleus collision creates the highest energy density system. Because of the size of the colliding system not all nucleons interact and they will depend on the impact parameter, b.

b


RHIC (Phenix) Results

22/1

⊥⊥

=dp

dndp

dnN

RNNhard

ABhard

binaryAA

0 spectra for central and peripheral

collisions.

Results show the suppression of 0 in central collisions.


ATLAS and Heavy Ions Interest in Heavy Ion Physics renewed after RHIC results showed

strong evidences for jet quenching.

ATLAS is a detector primarily designed for high pT physics at the LHC design luminosity and well suited for the study of jet physics. The calorimeter has a large coverage (||<4.9), excellent resolution and fine granularity.

Heavy Ion collisions produce a HUGE number of particles. Event generators such as HIJING predicts about dN/dy~6,000.

How well does ATLAS perform for Heavy Ion Physics?

Results shown here are obtained from full G3 simulations of the ATLAS detector

Hijing has been used, which is conservative because of the high particle multiplicities

All results are VERY preliminary


The ATLAS detector

Tile Calorimeter

Hadronic Endcap

Forward Calorimeter

Electromagnetic LAr

Inner Detector


Simulations

HIJING b=0 event in the ATLAS detector. Events for b=0-15fm were generated in the range of ||<3.2.


Global Measurements

x

z

y

Quantities such as energy flow, particle multiplicity, anisotropy in energy flow, permit us to characterize the event. Any particular measured quantity should be studied in function of these variables.

dN/d from the pixel detector compared to what is given by the event generator.


Impact Parameter Determination

Events in ATLAS can be characterized by the measurement of the event charged particle Multiplicity or Total Transverse Energy.

Correlation between impact parameter and number of hits in the pixel detector.

Comparison of the impact parameter resolution obtained by three distinct techniques.


Tracking with ID - Occupancies

Pixel Detector Silicon Tracker

Impact parameter b=0-1 fm, HIJING event generator.

Track reconstruction with the Inner Detectors is challenging due to the high occupancy. From the three systems, the TRT has very high occupancy that make it unusable for heavy ion physics.


Tracking Reconstruction

Track reconstruction performed with ATLAS tracking code using the Pixel and SC systems. Simulation include -rays. Efficiencies are slightly lower for two layer pixel configuration. Momentum resolution is approximately 2.4%.

Efficiency has a flat dependency with , except in the transition regions between barrel and endcap.


Jet reconstructionModifications of the jet properties by the “hot media” created by the nucleus-nucleus collision will provide a unique way to study it.

Hard scattered partons in the media radiate gluons and in the process “lose” energy (the overall energy is conserved). This could manifest as an increase in the jet cone size. The measurement of the fragmentation function distribution is the most direct way to observe any changes.


Jet Reconstruction

We have performed initial work on reconstructing jets in the heavy ion environment. Pythia jets were overlapped to HIJING produced “background” as means to produce jet events.

Heavy Ion “background” (HIJING) has a very soft particle spectra.

Remind you of the ATLAS calorimeter system:


Jet Reconstruction

Energy in 0.1x0.1 tower in the EM and HAD calorimeter for ||<3.2. Most of the energy is in the EM calorimeter

Energy in 0.1x0.1 tower as function of . The pronounced dips are the transiton region between barrel and endcap calorimeters.

PRELIMINARY


55 GeV Jet

Pythia only

The Result!

Pythia + Hijing mixed event.

After average background subtraction

For lower jet energies we found that it is easier to find jets if the first EM compartment is not included. Later the energy from the 1st compartment must be recovered.


280 GeV event

Plots for 280 GeV jets.

Preliminary efficiency numbers show that jet reconstruction efficiency is larger than 90% above 50 GeV.

Below 50 GeV the efficiency lowers to approximately 75% with an increase in the number of “ghosts”.

Resolution and Efficiencies are now being worked out!!! (well, they didn’t make it for this talk…)


Beauty quarkRadiative quark energy loss is qualitatively different for heavy and light quarks.

Finite velocity of heavy quarks at finite transverse momentum leads to suppression of co-linear gluon emission.

Tagging of the b jets is possible via the high pT muon in the spectrometer or via displaced vertex. We are currently investigating both possibilities.


B-taggingPreliminary study of the b-jet tagging using the Pixel and SCT detectors and the algorithm used for high pT proton-proton environment.

Left, the rejection of light quark jet as function of tagging efficiency for p-p, and right for heavy ions. In both cases W+H events were used. A combination of displaced vertex and muon tagging may improve the overall rejection factor.

PRELIMINARY!


Fragmentation FunctionWe are considering measuring the fragmentation function via the EM cluster in the jet or charged particle momentum in the jet. The study below was performed for 75 GeV Pythia generated jets.

Reconstructed EM cluster in the jet compared to the sum of 0 energies.

Reconstructed charged particle track in the jet compared to the given by the event generator. The efficiency is 85%.


Probes of deconfinement

Upsilon states (1s,2s,3s) span a large range in binding energy and thus their suppression pattern may allow for a mapping on the onset in the screening on the long range color confining potential.

state J/ψ χcψ' Υ(1 )s χb

Υ(2 )s χb' Υ(3 )s

[ }Mass GeV 3.096 3.415 3.686 9.46 9.859 10.023 10.232 10.355. . [ ]B E GeV 0.64 0.2 0.05 1.1 0.67 0.54 0.31 0.2

Td/Tc --- 0.74 0.15 --- --- 0.93 0.83 0.74

The detectors used for the Upsilon mass reconstruction are the Muon Spectrometer, Silicon Tracker and the Pixel Detector.


Probes of deconfinementInitial figures on mass resolutions using Upsilon events alone indicate a system resolution of 130 MeV, with an estimated S/B~0.6. Muons with pT>3GeV are tracked backwards to the ID and the mass calculated from the overall fit. Overlay with HIJING Event is now under way!


Proton-Nucleus physics Study of p-A collisions is important @ LHC

To provide baseline for heavy ion measurements. Physics intrinsically compelling

Nuclear Structure functionMini-jet production, multiple semi-hard scattering.Gluon saturation – probe QCD @ high gluon densityEtc...

In the pA environment we can fully benefit from ATLAS detector capabilities, e.g. tracking, because particle multiplicities are lower than in pp collisions at design luminosity.

Because of this “low” particle multiplicity we can run at high luminosity, e.g. 1031.

Astroparticle Physics interest.


Trigger DAQ

For Pb+Pb collisions the interaction rate is 8kHz, a factor of 10 smaller than LVL 1 bandwidth.

We expect further reduction to 1kHz by requiring central collisions and pre-scaled minimum bias events (or high pT jets or muons).

The event size for a central collision is ~ 5 Mbytes.

Similar bandwidth to storage as pp at design L implies that we can afford ~ 50 Hz data recording.

~200 Hz


Physics Program The initial goal is to determine the global Nucleus-Nucleus

collision properties by the measure of total ET, Nch and Flow.

There is interest in studying jet physics in heavy ion collision as a mean to probe the early stages of the system formed. This comprises in measuring jet (di-jet) cross sections, and measure jet properties in jet+jet, +jet, Z0+jet and *+jet channels.

Heavy quarks should have gluon radiation suppressed due to their mass. The B-jet should not be quenched.

A direct probe of deconfinement is the suppression of the Υ or Υ states. These can be reconstructed using the muon spectrometer and the inner detector.

Proton-nucleus collisions are interesting on its own and will provide a solid baseline for the understanding of AA system.

Ultra Peripheral collisions will be studied.


Conclusions and Outlook ATLAS is general purpose detector with excellent

performance for high pT physics.

Features like calorimeter coverage, granularity and resolution give us good potential for high pT probes in heavy ion collisions, e.g. jet quenching. ATLAS is complementary to ALICE and CMS.

The physics topics outlined in this presentation can be likely addressed with the present detector layout (except for zero degree calorimetry to study UPC).

For pA and light AA collisions the experimental environment is quieter than pp collisions at design L and therefore we can benefit from the full detector performance capabilities.

Heavy ion physics studies in ATLAS are progressing with the aim of preparing a Letter of Intent to LHCC by mid 2003.


EM calorimeter segmentation

heavy ion physics with the atlas detector helio takai brookhaven national laboratory [email protected]...

Documents

heavy ion physics

study of jet physics

energy flow

overall energy

atlas tracking code

impact parameter resolution

highest energy density

central collisions