190 likes | 299 Views
Nonequilibrium dilepton production from hot hadronic matter. Björn Schenke and Carsten Greiner 22nd Winter Workshop on Nuclear Dynamics La Jolla. Phys.Rev.C (in print) hep-ph/ 0509026. Outline . Motivation: NA60 + off-shell transport
E N D
Nonequilibrium dilepton production from hot hadronic matter Björn Schenke and Carsten Greiner 22nd Winter Workshop on Nuclear Dynamics La Jolla Phys.Rev.C (in print) hep-ph/0509026
Outline • Motivation: NA60 + off-shell transport • Realtime formalism for dilepton production in nonequilibrium • Vector mesons in the medium • Timescales for medium modifications • Fireball model and resulting yields • Brown-Rho-scaling RESULTS
Motivation: CERES, NA60 Fig.1 : J.P.Wessels et al. Nucl.Phys. A715, 262-271 (2003)
Motivation: off-shell transport medium modifications thermal equilibrium: (adiabaticity hypothesis) Time evolution (memory effects) of the spectral function? Do the full dynamics affect the yields? We ask:
Green´s functions and spectral function spectral function: Example: ρ-meson´s vacuum spectral function Mass: m=770 MeV Width: Γ=150 MeV
Realtime formalism – Kadanoff-Baym equations • Evaluation along Schwinger-Keldysh time contour • nonequilibrium Dyson-Schwinger equation with • Kadanoff-Baym equations are non-local in time → memory - effects
Principal understanding • Wigner transformation → phase space distribution: → quantum transport, Boltzmann equation… • spectral information: • noninteracting, homogeneous situation: • interacting, homogeneous equilibrium situation:
Nonequilibrium dilepton rate This memory integral contains the dynamic infomation • From the KB-eq. follows the Fluct. Dissip. Rel.: surface term → initial conditions • The retarded / advanced propagators follow
What we do… (KMS) follows eqm. temperature enters here → → (FDR) → (VMD) → (FDR) put in by hand
In-medium self energy Σ • We use a Breit-Wigner to investigate mass-shifts and broadening: • And for coupling toresonance-hole pairs: M. Post et al. • Spectral function for the coupling to the N(1520) resonance: k=0 (no broadening)
History of the rate… • Contribution to rate for fixed energy at different relative times: From what times in the past do the contributions come?
Time evolution - timescales • Introduce time dependence like • Fourier transformation leads to (set and(causal choice)) e.g. from these differences we retrieve a timescale… At this point compare We find a proportionality of the timescale like , with c≈2-3.5 ρ-meson: retardation of about 3 fm/c The behavior of the ρ becomes adiabatic on timescales significantly larger than 3 fm/c
Quantum effects • Oscillations and negative rates occur when changing the self energy quickly compared to the introduced timescale • For slow and small changes the spectral function moves rather smoothly into its new shape • Interferences occur • But yield stays positive
Dilepton yields – mass shifts Fireball model: expanding volume, entropy conservation → temperature m = 400 MeV ≈2x Δτ=7.5 fm/c m = 770 MeV T=175 MeV → 120 MeV Δτ=7.5 fm/c
Dilepton yields - resonances Fireball model: expanding volume, entropy conservation → temperature coupling on Δτ=7.2 fm/c no coupling T=175 MeV → 120 MeV Δτ=7.2 fm/c
Dropping mass scenario – Brown Rho scaling • Expanding “Firecylinder” model for NA60 scenario • Brown-Rho scaling using: • Yield integrated over momentum • Modified coupling T=Tc → 120 MeV Δτ=6.4 fm/c ≈3x B. Schenke and C. Greiner – in preparation
NA60 data m → 0 MeV m = 770 MeV
The ω-meson m = 682 MeV Γ = 40 MeV Δτ=7.5 fm/c m = 782 MeV Γ = 8.49 MeV T=175 MeV → 120 MeV Δτ=7.5 fm/c
Summary and Conclusions • Timescales of retardation are ≈ with c=2-3.5 • Quantum mechanical interference-effects, yields stay positive • Differences between yields calculated with full quantum transport and those calculated assuming adiabatic behavior. • Memory effects play a crucial role for the exact treatment of in-medium effects