Post on 05-Jan-2016
1
Tomoaki Hotta (RCNP, Osaka Univ.)
for
The LEPS Collaboration
Cracow Epiphany Conference, Jan 6, 2005
• Introduction• LEPS experiment• Results from new LD2 data• Summary and outlook
LEPS Results on +
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Theoretical Prediction of Baryon
M1890-180*Y] MeV
D. Diakonov, V. Petrov, and M. Polyakov, Z. Phys. A 359 (1997) 305
(Chiral Soliton Model)
• Exotic: S = +1– cannot be (qqq) state
• Low mass: 1530 MeV• Narrow width: ~ 15 MeV (30 MeV)*• J=1/2+
*The width corrected by R. Jaffe (hep-ph/0401187)
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First evidence of from LEPS
n K KK n
1.540.01 GeV< 25 MeVGaussian significance 4.6Target: neutron in Carbon nucleus
Background level is estimated by a fit in a mass region above 1.59 GeV.
Assumption:• Background is from non-resonant K+K- production off the neutron/nucleus• … is nearly identical to non-resonant K+K- production off the proton
+
Phys.Rev.Lett. 91 (2003) 012002
hep-ex/0301020
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Evidence for Pentaquark StatesSpring8 ELSA
JLab-p
HERMES
ITEP
pp ++.
COSY-TOFDIANA
SVD/IHEP
JLab-d
ZEUSCERN/NA49
H1
Nomad
a lot of evidence
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Questions:
• “Existence of the + ” is the most important issue
– some inconsistencies in the measured mass & width.
– negative results (mainly) from high energy experiments.
→ Can we see the peak again in the new LEPS data ?
• True mass, width• Spin & Parity
• Production mechanism, cross sections…
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• Data taken from Oct. 2002 to Jun. 2003.
• ~2×1012 photons on a 15cm-long LD2 target.
• Less Fermi motion effect.
• LH2 data were taken in the same period with ~ 1.4×1012 photons on the target.
# of photons: LH2:LD2 ≈ 2:3
we expect
# of events from protons: LH2:LD2≈ 2:3
# of events: LH2:LD2≈ 1:3
LEPS New LD2 and LH2 runs
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Super Photon ring-8 GeV SPring-8
• Third-generation synchrotron radiation facility
• Circumference: 1436 m
• 8 GeV
• 100 mA
• 62 beamlines
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Laser Electron Photon facility at SPring-8
in operation since 2000
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LEPS detector
1m
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Charged particle identification
Mass(GeV)
Mo
men
tum
(G
eV
)
K/ separation (positive charge)
K++
Mass/Charge (GeV)
Eve
nts
Reconstructed mass
d
p
K+
K-
+-
(mass) = 30 MeV(typ.) for 1 GeV/c Kaon
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Reaction diagrams
pK
nKnp
nKpKpn
)1520(
)()1520()(
)()(
*
*
n
K─
K+
n+
p p
p
K+
K─
p
n n
N (1020) NK+K- N
S=+1
S=-1
“Exotic”
“Standard” baryon
Meson resonance
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background
N/
N
rati
o
Invariant mass (K+K-) (GeV)
Eve
nts
Invariant mass (K+K-) (GeV)
Real data
MC()
N : Real data – MC()N : MC()
ratio was almost energy independent.
13E dependent cut point : “N/N ratio × Relative acceptance = R”
exclusion cut
Invariant mass (K+K-) (GeV)
MM
( ,
K- )
(G
eV
)
1.8<E<2.0 GeV 2.0<E<2.2 GeV 2.2<E<2.4 GeV
Monte Carlo simulation (K+K-n 3 body phase space)
M=1.019
Expected signal region
“Rerative acceptance” = N(1.50<MM(,K-)<1.55)/N(all)
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Energy dependent exclusion cut
E(GeV)
R=0.01
R=0.05
R=0.20K
K in
v. M
ass
(GeV
)
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Cut dependence of K+ missing mass for the LH2 data
MM (GeV)
MM (GeV)
MM (GeV)
R=0.01 0.02 0.03
0.05 0.07 0.10
0.20 0.50 1.00
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Cut dependence of K+ missing mass for LD2 data
MM (GeV)
MM (GeV)
MM (GeV)
0.02 0.030.01
0.05 0.07 0.10
0.20 0.50 1.00
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Comparison of MM(,K+) for
the LH2 and LD2 data
MM (GeV) MM (GeV)
LH2:LD2 ratio of events is ~2:3
consistent with the expectation.
LH2LD2
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Comparison of MMd(,K+K-)
MM (GeV) MM (GeV)
Remove dKKd contributions by requiring MMd(,KK)>1.89 GeV
LH2 LD2
Mising mass for dKKX
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After removing deuterium elastic scattering
contributions
MM (GeV) MM (GeV)
Further require 0.89<MM(,KK)>0.99 GeV
S/N at (1520) peak is better than 1.
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Cut dependence of K+ missing mass for LD2 data after MMd cut
MM (GeV)
MM (GeV)
0.20
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Check if the cuts generate the “+” peak artificially by
analyzing KKN phase space MC
sample MC sampleLH2 data
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KKN phase-space MC data after applying the same
selection cuts.
MM (GeV)
MM
(G
eV)
MM (GeV)
No narrow peak in MM(,K-).
Symmetric between K+ and K-.
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MC data after the cuts.
MM (GeV) MM (GeV)
MM
(G
eV)
No narrow peak in MM(,K-).
contribution is estimated to be less than 15% of the final sample.
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MM(,K-) for the LH2 data
MM (GeV)
MM(GeV)
0.20
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+ search in MM(,K-) of the LD2 data
• Apply the same selection cuts.• See if the peak is reproduced.• See if the peak has reasonable
dependence on the exclusion cut variation.
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MM(,K-) for the LD2 data
0.20
MM(GeV)
MM(GeV)
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Summary of LD2 data analysis
MM (GeV)
• K+K- from LD2 target
• MMd(,K+K-)>1.89 GeV
• 0.89< MM N (,K+K-)<0.99 GeV
• exclusion cut at R=0.2
• Fermi motion correction
Reliable background estimation is essential to confirm the existence of the peak.Statistics of LH2 data is small.
increase statistics by mixed event technique
(K. Hicks, Ohio univ.)
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Mixed event analysis with
KKN phase space MC data
• Mix K+, K-, from different events.
• Apply the same selection cuts again on the mixed events.
• Check if the shape of the original distribution is reproduced by the mixed events.
MM (GeV)
Mixed event analysis seems to work fine for the exclusive reaction!
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Mixed event analysis
MM (GeV) MM (GeV)
• LH2 mixed events are obtained by removing L(1520) contributions.
• The mixed event spectra are compared with the LD2 missing mass spectra.
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After removing (1520)
MM (GeV)
• Background level around 1.53 GeV in 4 bins is ~220 events IF we take the mixed event BG method.
• The excess above the BG level is ~90 events.
•The peak position, width, significance strongly depends on the BG shape.
• The mixed event BG method may not work if the major BG is due to narrow resonances in K-p or K+K- channels.
•We need further BG study and it is in progress.
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Summary and outlook
• Evidence for an S=+1 baryon (+) around 1.54 GeV with a narrow width has been observed.
• LEPS higher statistics experiment has re-observed the peak. – unlikely to be due to statistical fluctuations.
• Need to understand the “background” shape.• Further analysis in progress.
• Experiment with larger acceptance detector (TPC) is planned in near future.