 0  fit update

1. 0 fit update P.Gauzzi

2. Outline • Kaon Loop • Systematics on the fit parameters • Fit with fixed VDM • No Structure • systematics • fit with free VDM • KL and NS fits with Adler zeros • New version of NS model

3. KL Correlation coefficients Ma0 1.000 ga0KK0.931 1.000 ga00.584 0.550 1.000  0.277 0.236 0.156 1.000 Br(VDM) -0.252 -0.327 -0.513 0.130 1.000 R0.004 -0.180 -0.111 0.008 -0.038 1.000

4. KL Systematics • Sensitivity to fixed parameters • ga0' = -1.13 ga0KK (4q) vs ga0' = 1.2 ga0KK (qq) • gK+K─ = 4.49  0.07 • Normalization (N  1) • Data-MC discrepancy for the wrong pairing fraction 11.5% (data) vs 14%(MC) • Sensitivity to the starting values of the parameters ( 10% variations < 0.1%)

5. Systematics (KL) • Relative variations

6. KL with fixed VDM • Br(VDM) = 410-6 (same as NS fit) • Worse 2 probability

7. NS Systematics • Sensitivity to fixed parameters Ma0 = 982.5 MeV (KL fit) vs 985.1 MeV (PDG) • Normalization (N  1) • Data-MC discrepancy for the wrong pairing fraction 11.5% (data) vs 14%(MC) • Sensitivity to the starting values of the parameters (10% variations < 0.2%)

8. NS Correlation coefficients ga0KK 1.000 ga00.849 1.000 ga00.885 0.971 1.000 R-0.226 -0.261 -0.309 1.000 a00.858 0.793 0.905 -0.275 1.000 00.584 0.787 0.805 -0.283 0.768 1.000 a1 0.684 0.707 0.813 -0.253 0.933 0.836 1.000 10.807 0.912 0.936 -0.294 0.868 0.931 0.816 1.000 • Large correlations

9. NS • Relative variations • Large correlations also with the a0 mass • Strange behaviour for N  1

10. NS with free VDM • Br(VDM) as free parameter (as for KL) • No sensitivity to VDM • Better fit quality • Couplings more similar to KL results (ga0 still compatible)

11. Fit with Adler zeros • According to some theoreticians the Adler zero is needed as a consequence • of Chiral Symmetry (however there is no general consensus) • It forces the PP interaction to vanish close to threshold: • I tried to include them into the fit functions: in order not to change the • meaning of the parameters I used:

12. KL fit with Adler zeros • With A.z. • Without A.z. M (MeV) • Fit quality improves • All relevant parameters become larger

13. NS with Adler zeros • The fit convergence improves: no need to fix the a0 mass • However according to Gino no Adler zeros should be put in the model, but…

14. New model • t’Hooft, Isidori, Maiani …. “A theory of Scalar Mesons” arXiv:0801.2288 • Scalars are “tetraquarks” • “Instanton” induced transitions to explain decays like f0 • All couplings are written in terms of 2 parameters: cf and cI (|cI|<<| cf |) • Pseudoscalars appear in the effective lagrangian with derivative couplings: • From the technical point of view of the fit, the effect is very similar • to the Adler zero

15. New NS fit • The mass is in agreement with KL and with PDG • cf=6.6 GeV-1 cI=1.6 GeV-1 (cf= 22 GeV-1 cI= -2.6 GeV-1 best fit by t’Hooft et al.)

16. Conclusions • We should decide which fit show in the paper • KL fit is stable • NS has some problems; what systematics should we quote ? • NS with VDM free goes in the same direction as KL • Very small VDM contribution • Adler zeros improve the convergence; are they really needed ? • New NS model: we should discuss the results with the authors (we are in contact with A.Polosa in Rome)

17. Systematics from photon pairing • Data • Right p. • Wrong p. • C(a0) is the difference between the • first and the second photon combination • for the a0 hypothesis • Two component (right and wrong pairing) • fit to the  C(a0) distribution of the data • (final sample) • Right and wrong pairing shapes from MC • wrong pairings = (11.5 ± 0.70) % • (from MC 14 %)  C(a0)

18. Systematics from photon pairing • From C(a0) between the first and • the second best combination • Wrong pairings: data  (11.5 ± 0.70) % • MC  14 % • Check done by scaling the off-diagonal • part of the efficiency matrix by 0.115/0.14 • and the diagonal region accordingly • to conserve normalization Mrec (MeV) Mgen (MeV)