Charm physics DN interactions in nuclear matter
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Transcript of Charm physics DN interactions in nuclear matter
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Charm physics
DN interactions in nuclear matter
Clara Estela Jiménez Tejero
National Nuclear Summer School 2007, Tallahassee, Florida
Advisors:I. Vidaña, A. Ramos
T. Mizutani, A. Ramos, hep-ph/0607257
J.Hofmann and M.F.M.Lutz, Nucl. Phys. A763, 90 (2005)
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Index
I. Discovery of charm
II. Motivation
III. Coupled Channel Approach model for solving DN interactions -Results in free space
IV. Conclusion and future perspectives
V. Panda experiment at GSI (if I have time)
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Charmonium discovery
October, 1974Simultaneous discovery:
• Ting et al. at BNL AGS• Richter et al. at SLAC SPEAR
p + Be→ e+e- + X at AGS
e+e- annihilation
1976 Nobel prize in physics
Very narrow peaks -> very long lifetimes (10-20s): thousand of times longer than expected!
In both experiments a
peak was found at 3.1 GeV
New kind of property forth type of quark!
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Example of decay’ → J/ + + + - Followed by J/ → e+e-
Decay of J/psi lowest level in lighter particles -> 90% decay to lighter quark particles (pions, kaons)-> Rarely decays to an electron and a positron (or muon and antimuon)
photonspions
electronsmuons
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Techniques in 80´s made possible to see charm particles directly by their trails, but how?
You just need to collide, for example, a photon with a proton …
PHOTON PROTON
Creation of charmed particles
Charm quarks combine with lighter quarks (u, d, s) to form either barions or mesons
PHOTON
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Production of charmed particles in the bubble chamber (SLAC) in 1980
2 mm
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Can be produced in pairs (D+,D-)
• in heavy ion experiments:
• or antiproton anhilation experiments (PANDA at FAIR) on protons and nuclei:
… production of charm particles at
present
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Motivation Why is important to understand the interaction of charmed mesons in a hadronic medium?
If the mass of the D (and Dbar) mesons gets reduced appreciably in the medium (cold or hot), this would provide a conventional hadronic physics explanation to explain J/ supression (attributed to be a signal for the formation of a Quark-Gluon Plasma)
Hints that a D Dbar meson-pair could feel attraction: an open charm enhancement has been observed in nucleus-nucleus collisions by the NA50 Collaboration
D and Dbar in the medium
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KN and DN are “similar” systems:Apparent similarity in their coupled channel nature by their association with the Lambda resonances: Presence of the c(2593) (udc)
(plays a similar role as the (1405) (uds) in KN dynamics)
D and Dbar mesons:
Similar to Kbar K:
Why do we believe in the “couple channel approach” model that we use?
Other methods like QCDSR and NMFA become innapropiate when the 2-body interaction:Strongdominated by intermediate bound states or resonances and/orstrongly coupled to other channels
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D mesons in symmetric nuclear matter:DN couple-channel equations approach
• First step: (1)-> Solving Bethe-Salpeter
equation in free space
• Second step: (2)-> Solving Bethe-
Salpeter equation in nuclear medium.
-> T is the transition operator matrix.-> The propagator G, diagonal matrix in which every element is the product of single-particle propagator for a meson and a barion.-> The potential V, whose elements are Weinberg-Tomozawa type meson-baryon interactions.
(1)
(2)
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In-medium effects
Pauli blocking on intermediate nucleons: consequence of Pauli principle, prevents the scattering to intermediate nucleon states below Fermi momentum, pf.
Dressing of mesons and baryons: Non perturbative strong interaction at low energies -> particles of intermediate loops interact through strong force with the nucleons of the Fermi sea, and their properties are modified with respect to those in free space.
In medium effects are contained in the propagator
D
Medium: isosymmetric nuclear matter (nucleons, Np=Nn)
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njnmkmkikmjmkmkikkjkikijij
njnmjmkmkikkjkikijij
mjmkmkjkikijij
kjkikijij
TGVGVGVVGVGVVGVVT
TGVVGVGVVGVVT
TGVVGVVT
TGVVT
ln
ln )(
)(
Self-consistent coupled channels method: Bethe-Salpeter equation
T = ( I - V·G )-1 ·VT = V+V·GT
V?
G?
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)3245(´),3085(),3071(),2960(
),2835(),2810(),2589(:)0,0,1(´
cscc
cc
DKK
DNSIC
)3415(´),3160(),3071(),3005(
),2960(),2810(),2589(),2425(:)0,1,1(´
cscc
ccc
DK
KDNSIC
The sectors of our interest:In S-wave and JP=(1/2)-, two different
channels
First channel with seven states:
Second channel with eight states:
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q1 q2
p1 p2
V Light vector meson exchange
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Pseudoscalar meson fields
vector meson fields
barion fields
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t-channel exchange of vector mesons:
universal vector coupling constant
chiral symmetry in the light sector imposed
W.T interaction
-> With these approximations and projecting in s-wave:
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I=0 I=1
Coefficients C=0, S=0
Li · Lj = [kinetic term]·Ci,j
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… solving T matrix in the free space …
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))()((
1
)(
1
)(
1
)2()(
22200
004
4
imkQkQ
ikEkikEkE
MkdisG
i
iii
ii
all 4-momenta are given in the lab frame
Ei and Mi is the energy and mass of the baryon mi the mass of the meson
Propagator in free space
q1=(q10,q1)q2=(q20,q2)
p1=(p10,p1) p2=(p20,p2)
s = (Q0)2 – (Q)2 Energy of mass frame
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Free space DN amplitudes
I=0 I=1
c(2595) c
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T matrix in the nuclear matter …
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G in nuclear matter
T = V+V·GT
V
GG in free space
Ci,j
T = ( I - V·G )-1 ·V
D N Intermediate states DN
Summary
(Li · Lj = [kinetic term]·Ci,j)
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Conclusions …
-> DN interaction in coupled channels from a model (inspired on the work of Hofmann and Lutz)
-> In free space, we generate the c(2595) dynamically in I=0. The same interaction generates a I=1 wide resonance which we denote as c(2770)
… and Future
-> We will implement the medium effects on the DN amplitudes (Pauli blocking, self-consistent dressing of D meson, dressing of ) self-consistently.
Ds also develops a self-energy
-> Solve C=1 S=1 DsN problem in the medium and incorporate Ds self-energy in our coupled-channel problem (DN strongly coupled to DsY)
[M.F.M.Lutz, and C.L.Korpa, Phys. Lett. B 633,43 (2006)]
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thanks for your
patience …
… so early
in the
morning
Question time
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Panda menu- Charmonium spectrospcopy- Gluonic excitations (hibrids, glueballs)- Open and hidden charm in nuclei- -ray spectroscopy of hypernuclei
http://www-panda.gsi.de/auto/_home.htm
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Characteristics HESR 10^11stored antiprotons1.5 -14.5 GeVL= 2 x 1032cm-2s-1δp/p ≥ 10-5σx≥ 50 μm