pp and d-au at rhic
DESCRIPTION
pp and d-Au at RHIC. Fuming LIU (IOPP, Wuhan), Tanguy Pierog, Klaus Werner. Contents: Interesting data from RHIC High parton densities pp and d-Au results Conclusion. August 9-14, 2004, CCAST, Beijing. Interesting data from RHIC. The nuclear modification factor - PowerPoint PPT PresentationTRANSCRIPT
pp and d-Au at RHICpp and d-Au at RHIC
Contents: • Interesting data from RHIC• High parton densities• pp and d-Au results• Conclusion
Fuming LIU (IOPP, Wuhan),Tanguy Pierog, Klaus Werner
August 9-14, 2004, CCAST, Beijing
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 22
1.1. Interesting data from Interesting data from RHICRHIC
The nuclear modification factor
shows interesting features: ppAA
NR
coll
1
• AuAu: much smaller than one for central collisions
• d-Au: bigger than one for central collisions
charged hadrons / 2 minimum bias STAR col. data
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 33
Centrality dependence of the nuclear modification factor from top to bottom: 0-20%, 20-40%, 40-60%, 60-88%
Rapidity dependence of the nuclear modification factor from top to bottom: eta=0, 1, 2.2, 3.2
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 44
Nuclear modification factor R > 1 implies that
partons with higher density in d-Au than in pp
involve the interactions.
How to formulize and simulate this high parton
densities in a Monte Carlo generator?
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 55
2. High parton densities2. High parton densitiesParton-parton scattering:
Same symbol for soft and hard.
rapidity plateau
Scattering with many partons:
No nuclear effect Nuclear modification factor R=1.
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 66
With high parton densities in target, a parton in projectile may interact with more partons in the target, e.g.:
Multiple ladders
Affects:• multiplicites• hadronization properties
elastic interaction
interference with simple diagram and provide negative contrib. to cross section (screen)
Rapidity gap
(high mass Diffraction)
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 77
We try to put all possibilities We try to put all possibilities togethertogether
In a simple and transparent way;In a simple and transparent way;
Using only simple ladder diagrams between projectile and Using only simple ladder diagrams between projectile and
target;target;
Putting all complications into “projectile/target excitations”, Putting all complications into “projectile/target excitations”,
to be treated in an effective way.to be treated in an effective way.The number of partons in projectile/target which can interact with a parton in target/projectile is the key quantity, we define it as Z p/T.
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 88
The contribution of simple diagram
')()( xx
For the screen contribution:
With reduced weight
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 99
)))31(log(1
11(2max
TZ
)exp(1)(
)(
2
22
0P/Tnucleons 0P/T
xxa
xg
bbg
EEZ
So we use
Z should increase with collision energy, centrality and atomic number
with
So we use
Adding the screening diagram gives the contribution
')()( xx
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1010
For the diffractive contribution:
The flat line represents a projectile excitation.
For the multiple ladder contribution:
A target excitation representsSeveral ladders
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1111
How to realize projectile/target excitation?
We suppose an mass distributed according toWe suppose an mass distributed according to For masses exceeding hadron masses, we take strings.For masses exceeding hadron masses, we take strings. To realize the effects of high parton density, string proTo realize the effects of high parton density, string pro
perties are supposed to depend on perties are supposed to depend on ZZ , e.g.: , e.g.:
2/1 M
),1 ,min()( max Zfzf
)(t0
breakbreakt Zfp p
0.3 ,3max fwith
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1212
The formalism:The formalism: Cut diagram techniqueCut diagram technique Strict energy conservationStrict energy conservation Markov chains for numericsMarkov chains for numerics
Our simulations tell that the number of “visible”Partons in projectile by a parton in target,6 Z:Au-d
2 :pp
projectile
projectile
Z
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1313
3. proton-proton results a. multiplicity distribution:
Left to right: contributions from 0, 1, >=2 Pomerons
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1414
3. proton-proton results b. pseudo-rapidity distribution:
UA5 data
PHOBOS data
Central ladders (Pom’s)Target excitations / Projectile excitations
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1515
3. proton-proton results c. Transverse momentum distribution:
data: PHENIX
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1616
3. proton-proton results c. Transverse momentum distribution:At different rapidity regions, data: BRAHMS
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1717
3. d-Au results a. pseudo-rapidity distribution:
Central ladders (N Pom > 1) Central ladder (N Pom =1)
Target excitations / Projectile excitations
Minimum bias
Centrality dependence
#
#
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1818
3. d-Au results c. Transverse momentum distribution, the nuclear modification factor R.
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 1919
The centrality dependence of nuclear modification factor R.
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 2020
The rapidity dependence of nuclear modification factor R.
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 2121
Some other good resultsSome other good results Results on identified hadrons, e.g. Results on identified hadrons, e.g.
The nuclear modification factor R for d-Au The nuclear modification factor R for d-Au collisions as a function of transverse collisions as a function of transverse momentum momentum
The particle ratios as a function of transverse The particle ratios as a function of transverse momentum for pp and d-Au collisionsmomentum for pp and d-Au collisions
The number of triggered jets at near The number of triggered jets at near side and away side for pp and d-Au side and away side for pp and d-Au collisions.collisions.
2004-8-102004-8-10 F.M.Liu, CCAST, BeijingF.M.Liu, CCAST, Beijing 2222
ConclusionsConclusions Motivated by the recent RHIC data in pp and d-Au collisions, we stuMotivated by the recent RHIC data in pp and d-Au collisions, we stu
dy the behaviors of nuclear modification factor.dy the behaviors of nuclear modification factor. The behaviors change with collision energy and centrality (includinThe behaviors change with collision energy and centrality (includin
g the atomic numbers of projectile and target).g the atomic numbers of projectile and target). We simulate the R behavior for d-Au collisions successfully and find We simulate the R behavior for d-Au collisions successfully and find
the high parton density plays the key role for it.the high parton density plays the key role for it. There are still something to do, e.g. adding the interactions of prodThere are still something to do, e.g. adding the interactions of prod
uced particles, to explain well the target side data of d-Au collision uced particles, to explain well the target side data of d-Au collision and explain Au-Au collisions.and explain Au-Au collisions.
Thanks !Thanks !