Recombination of Quarks (and Statistical Model) - PowerPoint PPT Presentation

1 / 48
About This Presentation
Title:

Recombination of Quarks (and Statistical Model)

Description:

Very much unlike hydrodynamics (mass ordering) Trento Hadronization. 19. Rainer Fries ... Hydrodynamics didn't save the day. Trento Hadronization. 21. Rainer ... – PowerPoint PPT presentation

Number of Views:45
Avg rating:3.0/5.0
Slides: 49
Provided by: Rainer94
Category:

less

Transcript and Presenter's Notes

Title: Recombination of Quarks (and Statistical Model)


1
Recombination of Quarks (and Statistical Model)
  • Rainer Fries
  • Texas AM University RIKEN BNL

Workshop on Hadronization ECT, Trento, September
3, 2008
2
Overview
  • Hadronization Introduction
  • RHIC Results
  • Recombination Models
  • Dilute Systems
  • Conclusions

3
Thoughts on Hadronization
4
Hadronization
  • Formulation of the Problem
  • How does an ensemble of partons C turn into an
    ensemble of hadrons H (w/ or w/o being coupled to
    a medium or spectators).
  • Solving this problem is rather hopeless.
  • Less ambitious look for special cases in which
    some non-trivial statements can be made.

5
Hadronization
  • Can the parton ensemble C be well-defined?
  • It is an intermediate state in a quantum field
    theory!
  • C and Y are unobserved in a scattering reaction
    AB ? HX
  • We have to sum over all possible pairs (C,Y)
  • Interference between (C,Y) and (C,Y) in
    amplitude and complex conjugated amplitude.
  • Probably it is not always possible to have well
    defined C with probabilistic interpretation!
  • But for all successful descriptions of
    hadronization this is the case.

6
Example Fragmentation
  • Single inclusive production of a single hadron h
    at large momentum (e.g. in ee-, pp)
  • QCD factorization process dominated by single
    parton in the intermediate state
  • No statement about hadronization itself.
  • But now one can write down a well-defined
    operator definition for the process with a
    probabilistic interpretation a fragmentation
    function
  • These matrix elements can be measured and have
    certain universality properties. They are very
    hard to calculate.

Collins and Soper many others since
7
Example Hard Exclusive Processes
  • Hard process in which nucleon stays intact, e.g.
    form factor in p ? ? p

8
Example Hard Exclusive Processes
  • Hard process in which nucleon stays intact, e.g.
    form factor in p ? ? p
  • Here parton ensemble C complete
    set of valence quarks of the nucleon
  • Sensitive to matrix element
  • ? nucleon light cone wave function
  • ? describes amplitude uud ? p
  • resembles recombination!

Chernyak and Zhitnitsky Brodsky and Lepage
9
Example Hard Exclusive Processes
  • Some constraints on ? from
    symmetries, some experimental
    constraints at least for
    pions.
  • In terms of light cone fraction x
  • Caveat
  • The way a hadron looks depends
    on what and
    how we measure.
  • Hard exclusive LC wave functions are
    special perturbative scale,
    infinite
    momentum frame,
    exclusive
    process.

E791 ?A?2J
How we see a hadron depends on
which process we use to probe
the resolution of the process
the reference frame.
10
Statistical Model
  • Statistical hadronization avoids the question of
    an explicit initial parton state.
  • hadrons born into equilibrium
  • But it invites the thought that some kind of
    statistical description should also be available
    for the partonic side of the process.
  • SHM certainly not applicable to exclusive
    processes

SHM lives here
How can it be connected to this?
11
Hints from RHIC
12
Hot Nuclear Matter
  • Early universe
  • A hot soup of quarks gluons
  • Phase transition to hadrons
  • Temperature T 1012 K
  • Lattice QCD
  • Phase transition or cross over at Tc 170 192
    MeV (_at_ ?B 0)
  • ? critical point ?
  • Strongly interacting partons or weakly
    interacting gas above Tc?

Karsch et al.
13
Jet Quenching
  • RHIC strong quenching of high-PT pions and
    kaons.
  • Energy loss of leading parton.
  • Naïve pre-2002 expectation hadron production
    from jets above PT 2 GeV.

Nuclear modification factor
14
Jet Quenching Baryon Puzzle
  • RHIC strong quenching of high-PT pions and
    kaons.
  • Energy loss of leading parton.
  • No jet quenching for baryons? (RAA , RCP 1)
  • Seen for PT 1.5 5
    GeV/c.
  • Baryon Anomaly at
    intermediate PT.

PHENIX
15
Baryon Puzzle
  • Proton/pion ratio gt 1 at PT 4 GeV in AuAu
    collisions.
  • Expectation from parton fragmentation p/? 0.1
    0.3
  • As measured in pp and ee-

PHENIX
16
Baryon vs Meson
  • General baryon/meson pattern p, ?, ?, ? versus
    K, ?, ?, K, ?

17
Elliptic Flow v2
  • Azimuthal anisotropy for finite impact
    parameter b gt 0
  • 3 mechanisms to translate spatial
    anisotropy in the initial state into

    momentum anisotropy in the final state.

Turbide, Gale, RJF
18
Elliptic Flow Scaling
  • Scaling first found experimentally
  • n number of valence quarks
  • Very much unlike hydrodynamics (mass ordering)

19
Elliptic Flow Scaling
  • Low PT scaling with kinetic energy
  • Implied by hydrodynamics.
  • Scaling close to perfect.

20
Recombination Models at RHIC were born out of an
apparent failure of jet fragmentation at
intermediate PT
Hydrodynamics didnt save the day.
21
Why not Hydro?
  • Baryon vs meson doesnt seem to be compatible
    with either hydro nor the statistical model.
  • No mass effect ? behaves like a pion (m? ? mp,
    m? gtgt m?)

STAR
STAR
22
Recombination Models
23
Dense Parton Systems
  • Basic idea
  • Fragmentation limit of hadronization for very
    dilute systems (parton density ? 0)
  • Opposite limit thermalized phase of partons
    just above Tc
  • No perturbative scale in the problem (T ? ?QCD)
  • Naively recombine partons that
    are already filling phase
    space.

24
Instantaneous Coalescence
  • Simple realization of a recombination model
  • Recombine valence quarks of hadrons
  • Dressed quarks, no gluons
  • Instantaneous projection of quark states (density
    matrix ?) on hadronic states with momentum P
  • Effectively 2 ? 1, 3 ? 1 processes
  • Projection conserves only 3 components of
    4-momentum.

25
Instantaneous Coalescence
Meson Wigner function
Production hypersurface
  • Hadron spectra can be
    written as convolution of

    Wigner functions W, ?
  • Replace Wigner function by
    classical phase space
    distribution
  • MC implementation available
  • Collinear approximation
  • light cone formalism, PT gtgt M

Quark Wigner function
Greco, Ko Levai
RJF, Müller, Nonaka Bass Hwa Yang also
Rapp Shuryak
Can be modeled with hard exclusive light
cone wave functions
26
Transport Approach
  • Boltzmann approach applied to ensemble of quarks
    and antiquarks scattering through meson
    resonances.
  • Breit-Wigner cross sections
  • Properties
  • Conserves energy and momentum.
  • Finite time to reach equilibrium.
  • First studies good description of spectra and
    elliptic flow compatible with KET scaling.
  • Baryons difficult.

Ravagli Rapp Ravagli, van Hees Rapp
27
The Thermal Case
  • Thermal parton spectra yield thermal hadron
    spectra.
  • For instant. recombination (collinear case)
  • Should also hold in the transport approach.
  • Automatically delivers NB NM if mass effects
    are suppressed
  • Details of hadron structure are not relevant for
    thermal recombination at high momentum (collinear
    case).
  • Wave function can be integrated out.
  • Important for elliptic flow scaling.
  • Also seen numerically in full 6-D phase space
    coalescence.


28
Exp Power Laws
  • Comparison of different scenarios
  • Power law parton spectrum
  • Recombination is suppressed
  • Good QCD factorization should
    hold at least for
    asymptotically
    large momentum
  • Exponential parton spectrum
  • Recombination more effective
  • Even larger effect for baryons

fragmenting parton ph z p, zlt1
recombining partons p1p2ph
29
Phenomenology
  • Dual model of hadron production
  • Recombination pQCD/fragmentation.
  • Using thermal quark spectra for recombination.
  • T 175 MeV
  • Radial flow ? 0.55
  • Fit to pion data ? predictive power for all other
    hadron species
  • Describes hadron production at RHIC in the
    collinear region (for PT gt 12 GeV/c).

30
Phenomenological Success
  • Recombination of thermal partons dominates up to
    4 GeV/c for mesons, 6 GeV/c for baryons

Greco, Ko Levai
RJF, Müller, Nonaka Bass
RJF, Müller, Nonaka Bass
31
Particle Ratios Statistical Model
  • Comparison of ratios to statistical model
  • SM is formally recovered by the instant.
    recombination model in the limit P ? ? for
    thermal quark spectra.
  • In reality
  • Deviations at low PT due to mass effects.
  • Jet physics takes over at around 4-6 GeV/c.
  • Modern data

STAR
32
Elliptic Flow Scaling
  • Assume universal elliptic flow v2p of the partons
    before the phase transition
  • Recombination prediction
  • Factorization of momentum
    and position space
  • Recover scaling law for infinitely narrow wave
    functions
  • Scaling holds numerically also for less special
    choices.

Momentum shared fractions x and 1-x
33
Elliptic Flow Scaling
  • Data Compilation

34
Elliptic Flow in Transport Approach
  • Kinetic energy scaling preserved going from the
    quark to the hadron phase.
  • Test with light and heavy quarks
  • Comparison with baryons?

Ravagli and Rapp
35
Dilute Parton Systems
36
Recombination in Other Systems
  • Recombination at very forward rapidity
  • No hard scale
  • Recombine beam remanants/spectators.
  • Leading Particle Effect (forward rapidities)
  • D/D? asymmetries clearly not described
    by pQCD
    fragmentation
  • Explained by recombination with beam
    remnants

K.P. Das R.C. Hwa Phys. Lett. B68, 459
(1977) Quark-Antiquark Recombination in the
Fragmentation Region
E791 ?? beam
E791 ?- beam hard cc production recombine c
with d valence quark from ?- gt reco of c with d
Braaten, Jia Mehen
37
Parton Shower Recombination
  • Attempts to treat reco fragmentation
    consistently
  • jets ? parton showers fitted to fragmentation
    functions
  • Also 2- and 3- quark constituent quark
    fragmentation recombination (? Q2 evolution)
  • HY Model recombine all partons
  • Partons soft/thermal showers from jets
  • 2-parton distribution function

Hwa, Yang
Majumdar et al.
Partons from 1 jets
soft-soft
Partons from 2 jets
soft-shower
38
HY Parton Showers
  • Shower parton distribution in the HY Model
  • Hard parton i
    shower parton j, momentum zpi
  • Determined by fits to fragmentation functions.
  • Could they resemble thermal boost ??

39
The Bigger Picture
  • Thermal recombination fragmentation treated
    equally
  • Can calculate cross terms.
  • Applicable to all kind of scattering systems.
  • Assume some exponential bulk (not thermal!) in
    pp or pA to account for soft physics.
  • Usually just adds two parameters.
  • E.g. check for baryon enhancement.

ee-
pp
pA
AA
40
Application to pA
  • dAu / pA at midrapidity
  • Cronin enhancement initial state broadening
  • At RHIC large final state effect seen baryon
    enhancement.
  • Pick-up reactions (soft/hard recombination)
    important

Hwa, Yang
41
Conclusions
42
Summary
  • Thermal medium probably ok
  • Jets (vacuum)
  • But there is a continuum of possibilities between
    those.

Stat. Model
Recombination
Stat. Model
Fragmentation
Shower Recombination Clusters
?
(?)
43
Just In
  • The Ridge and the Peak

?
  • Baryon/meson ratios
  • jet smaller than inclusive
  • and similar to pp
  • ridge similar to inclusive

?
STAR
pTtrig gt 4.0 GeV/c 2.0 lt pTassoc lt pTtrig
C. Suarez (STAR), poster, QM2008
AuAu 2ltpTtriglt3 GeV/c,CuCu3ltpTtriglt6 GeV/c
44
Backup
45
Quark Counting Rule for the QGP
  • Quark counting rules quark substructure in
    hadrons
  • Classic example counting valence quarks
  • RHIC a new quark counting rule
  • Subhadronic degrees of freedom are at work.
  • They act collectively observable v2 describes
    collective effect
  • Equilibrium / hydrodynamic behavior of this
    matter (?)
  • Deconfinement is reached.

46
Hadron Correlations
  • Jet-like correlations seen even at intermediate
    PT.
  • How to reconcile with thermal recombination?
  • Correlations induced by Soft/Hard Reco (pick up
    reactions)
  • Hadron correlations arise from correlations
    between soft partons

Hot spots fully or partially thermalized jets ?
correlated soft partons
47
Hadron Correlations
  • Jet like correlations seen in data even at
    intermediate PT.
  • How to reconcile with recombination?
  • Correlations induced by Soft/Hard Reco (pick-up
    reactions)
  • Hadron correlations arise from correlations
    between soft partons
  • Model with 2-body correlations

Preliminary RJF Nonaka frag-frag reco-reco
only
Near side
Away side
central
Meson trigger
Baryon trigger
peripheral
RJF, Bass Müller
48
LHC Preview
  • Recombination window might widen at LHC.
  • It depends on the interplay of increased redial
    flow and energy loss.

RJF Müller
Write a Comment
User Comments (0)
About PowerShow.com