Di-hadron correlations measurements from CMS · Associated hadron yield per trigger: Understanding...

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Di-hadron correlations measurements from CMS

Dragos Velicanu

Workshop on P- and CP-odd Effects in Hot and Dense Matter (2012)

6/23/2012 Dragos Velicanu Workshop on P- and CP-odd Effects in Hot

and Dense Matter (2012) 1

Understanding Initial Conditions

Goal: To understand initial conditions of PbPb and pp collisions through long range correlations of produced charged particles

Two views of possible PbPb initial conditions Probe the initial condition of proton structure

Understanding Initial Conditions

Goal: To understand initial conditions of PbPb and pp collisions through long range correlations of produced charged particles

CMS Detector

TRACKER (Pixels and Strips)

Very large coverage for tracking (|| up to 5.0)!

EM Calorimeter (ECAL) Hadron Calorimeter (HCAL)

Beam Scintillator Counters (BSC)

Forward Calorimeter

Muon System

PbPb and pp collisions at the LHC

Correlations of charged tracks

Event 1

Event 2

same event pairs

mixed event pairs

Signal pair distribution: Background pair distribution:

Correlations of charged tracks

Event 1

Event 2

same event pairs

mixed event pairs

Divide Signal by Background Associated hadron yield per trigger:

Correlation function

Event 1

Event 2

same event pairs

mixed event pairs

JHEP 09 (2010) 091

High multiplicity pp (N>110) 𝑠 = 7 𝑇𝑒𝑉

Associated hadron yield per trigger:

Understanding the pp correlations

“Near-side” (, ~ 0) correlations from single jets

“Away-side” ( ~ )

back-to-back jet correlations

High multiplicity pp: more than 8 times more particles are produced from a single collision than average, 7e-5 selection

Understanding the pp correlations

Minbias pp

High multiplicity MC

Striking “ridge-like” structure extending over

at ~ 0 Not seen before in

high multiplicity MC

nor MinBias pp!

Quantitative ridge Measurements

Zero-Yield-At-Minimum (ZYAM)

Ridge region: 2<||<4

Jet region: || < 1

Ridge || and multiplicity dependence

Zero-Yield-At-Minimum (ZYAM)

Ridge region: 2<||<4

Ridge is flat in ||

pT dependence of the pp ridge

Jet region ||<1 Ridge region: 2<||<4

PbPb correlations

pTtrig: 4–6 GeV/c

pTassoc: 2–4 GeV/c

CMS PbPb 2.76 TeV 35-40%

Pb Pb 35-40% centrality

arXiv:1201.3158

CMS PbPb 2.76 TeV

EPJC 72 (2012) 2012

PbPb correlations: Geometry

pTtrig: 4–6 GeV/c

arXiv:1201.3158

CMS PbPb 2.76 TeV

EPJC 72 (2012) 2012

𝑉2Δ cos(2 Δϕ)

PbPb correlations: Geometry

EPJC 72 (2012) 2012

PbPb correlations: Geometry?

pTtrig: 4–6 GeV/c

arXiv:1201.3158

CMS PbPb 2.76 TeV

EPJC 72 (2012) 2012

CMS PbPb 2.76 TeV

elliptic flow cos(2Δϕ) term not prominent

JHEP 07 (2011) 076

Ridge Region (2<|Δη|<4)

2 < pT

assoc < 4 GeV/c

PbPb correlations: Ridge Yield

CMS PbPb 2.76 TeV

arXiv:1201.3158

CMS PbPb 2.76 TeV

JHEP 07 (2011) 076

Ridge yield goes down at high pT

JHEP 07 (2011) 076

Associated yield

Ridge is flat in Δη

Ridge Region (2<|Δη|<4)

2 < pT

assoc < 4 GeV/c

Comparison of ridge in pp and PbPb

JHEP 07 (2011) 076

Qualitatively similar properties but not quantitatively

PbPb correlations: Geometry?

CMS PbPb 2.76 TeV

arXiv:1201.3158

CMS PbPb 2.76 TeV

JHEP 07 (2011) 076

PbPb correlations: Fluctuations

CMS PbPb 2.76 TeV

arXiv:1201.3158

CMS PbPb 2.76 TeV

JHEP 07 (2011) 076

Triangular flow

Elliptic flow

Triangular flow Elliptic flow

+ + + n=2 n=3 n=4 n=5

Two-particle correlation

PbPb correlations: Fluctuations

CMS PbPb 2.76 TeV

arXiv:1201.3158

CMS PbPb 2.76 TeV

JHEP 07 (2011) 076

PbPb correlations: Fourier Analysis

CMS PbPb 2.76 TeV

arXiv:1201.3158

CMS PbPb 2.76 TeV

JHEP 07 (2011) 076

Fourier decomposition:

PbPb correlations: Fourier Analysis

Fourier decomposition: EPJC 72 (2012) 2012

For flow driven correlations:

However,

• pT dependent flow fluctuation could break the factorization

• Non-flow could also factorize

factorization

“Factorization” seems to work

v2(pT) from correlation method derived using fixed pTassoc

of 1-1.5 GeV/c agrees well with EP method

Dihadron correlation

o HF Event plane

0-5% 15-20% 35-40%

Pb Pb Pb Pb Pb Pb

PbPb 2.76 TeV

pT (GeV/c)

0-5% 15-20% 35-40%

More Constraints from Higher vn

Schenke et. al., arXiv:1109.6289

Measure all vn to over-constrain the hydro calculations

Initial conditions (Glauber vs CGC)

More Constraints from Higher vn

Schenke et. al., arXiv:1109.6289

Measure all vn to over-constrain the hydro calculations

Initial conditions (Glauber vs CGC)

Summary

• pp-ridge extends out to at least || ≈ 4 , tends to flat in - long range correlation

• pp-ridge first appears at 3-4× average multiplicity and seems to saturate at 8-10×

• pp-ridge yield peaks at intermediate pTtrig ≈ 3

GeV/c and decreases at high pTtrig

• PbPb also exhibits long range correlations that rise and fall with pT

trig and centrality

• Precise measurements of higher vn will better nail down the PbPb initial conditions and /s

Backup

Factorization of Fourier Harmonics

Test of factorization:

VnΔ(1,1) VnΔ(1,2) VnΔ(1,3) VnΔ(1,m)

VnΔ(2,1)

VnΔ(3,1)

VnΔ(2,2) VnΔ(2,3) VnΔ(2,m)

VnΔ(3,2) VnΔ(3,3) VnΔ(3,m)

VnΔ(m,1) VnΔ(m,2) VnΔ(m,3) VnΔ(m,m)

pTtrig

pTassoc

Assuming factorization

Take low reference pT bin (1-1.5 GeV/c)

Check if vn(pT) can derive rest of matrix:

Factorization of Fourier Harmonics

Check if vn(pT) can derive rest of matrix:

Take low reference pT bin (1-1.5 GeV/c)

EPJC 72 (2012) 2012

Like-Sign vs Unlike-Sign pp ridge

No dependence on relative charge sign

Di-hadron correlations measurements from CMS · Associated hadron yield per trigger: Understanding...

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