La Fisica dei K a DA NE-2

1. La Fisica dei K a DANE-2 F. Bossi CSN1, Frascati 14-15 Ottobre 2005

2. Summary of the talk • DANE and KLOE 1999  2005 • PHYSICS ISSUES AT DANE2: • TESTS OF CPT • CHIRAL PERTURBATION THEORY • SOME PREDICTION OF THE STANDARD MODEL • DETECTOR ISSUES F. Bossi, CSN1, Frascati 14 Ottobre 2005

3. Some basic concepts (and numbers) A  meson decaying at rest produces pairs of neutral or charged kaons with branching ratios of ~34% and ~49%,respectively Daughter particles are monochromatic, Pch~ 125 MeV/c, Pneu ~ 110 MeV/c Parity conservation imposes the neutral state to be KSKL In resonant e+e collisions, particles fluxes are: 1.5 x 106K± pairs/pb1 1. x 106 KS KLpairs/pb1 F. Bossi, CSN1, Frascati 14 Ottobre 2005

4. A brief history of luminosity DANE performance up to April 2005 2 Peak Luminosity Integrated Luminosity Present day performance Lpeak ~ 1.4 x 1032 cm2s1 Best L dt ~ 200 pb1/month Total KLOE L dt ~ 2200 pb1 (2001,02,04,05) F. Bossi, CSN1, Frascati 14 Ottobre 2005

5. KLOE papers on K physics Plus (at least) as many in preparation F. Bossi, CSN1, Frascati 14 Ottobre 2005

6. Apossibleevolution of DANE The Laboratory is now studying the possibilty for an upgrade of the present facility There are a few options under consideration. The one that I will discuss here, and refer to as DANE-2 is: A -factory able to deliver7-10 fb1in one year, i.esome 109well taggedkaons of all species after 2-3 years of run I will also assume that the detector to be used is some more or less conservative evolution of KLOE. Therefore almost all of the figures about detection performances are based on measurements on real data F. Bossi, CSN1, Frascati 14 Ottobre 2005

7. K Physics issues at DANE-2 What studies can be performed using kaons at DANE-2?: • Tests of fundamental symmetries (CP, CPT) • Tests of prediction of Chiral Perturbation Theory • Tests of prediction of Standard Model For each of these three topics I will discuss some examples of measurements that can be performed at DANE2. The list reflects my present personal knowledge of the matter and mustbe considered asnon-exhaustive F. Bossi, CSN1, Frascati 14 Ottobre 2005

8. CPT F. Bossi, CSN1, Frascati 14 Ottobre 2005

9. CPT In the framework of quantum field theory (QFT), CPTconservation is a theorem. It is consequence of Lorentz invariance, locality as well as quantum mechanics The possibility of CPT violation is considered in several theoretical contexts that go beyond conventional QFT, for instance in models of quantum gravity CPT violation may manifest itself in many subtle ways different from the inequality of particle-antiparticle masses. This is mostly the realm of -factories F. Bossi, CSN1, Frascati 14 Ottobre 2005

10. CPT violation: the “standard” path In the standard description of the neutral K system, a charge asymmetry in semileptonic KL and KS decays is predicted due to CP and (possibly) CPT violation L = 2Re(K )   CPT is violated if S≠ L S = 2Re(K ) +  The most recent measurement are: L = (3322 ± 58 ± 47) x 106 KTeV, 02 S = (1.5 ± 10 ± 3) x 103 KLOE, ~400 pb1 F. Bossi, CSN1, Frascati 14 Ottobre 2005

11. Potentialities of DANE-2 forS Assuming present detection efficiencies and a modest improvement in systematic studies, at DANE-2 one could aim at a total error on S of order10-3 However it has already been shown that one can obtain an increase in acceptance up to a factor of 2 just by lowering the B field to 3 kGauss Present analysis, MC with detailed field map 400 pb-1 MC with LSF=0.5, with uniform axial B field 0.2 0.15 Acceptance 0.1 With some optimism one can hope to reach a sensitivity on Sbelow the 103 level 0.05 B (kG) 3 4 5 F. Bossi, CSN1, Frascati 14 Ottobre 2005

12. CPT and decoherence It has been suggested that quantum gravity could give rise to modification of standard QM, observed in decoherence effects together with CPT violation This can be observed in deviation of the behaviour of entagled systems (like KSKL from  decays) from the one predicted by standard QM F. Bossi, CSN1, Frascati 14 Ottobre 2005

13. CPT and decoherence: the EHNS model Ellis, Hagelin, Nanopoulos and (independently) Srednickiset up an evolution equation of the neutral K system containing three new CPT violating parameters ,, with dimensions of energy Naively, one expects ,,~ O(MK2 / MPlank) ~ 10-20 GeV PeskinandHuetworked out the expression of the usual double decay intensity of the KSKLpair from  decays in the EHNS framework There appear new bizarre terms in the distribution which allow to extract experimentally limits (or measurements) of these new parameters by proper fitting F. Bossi, CSN1, Frascati 14 Ottobre 2005

14. Fixing the EHNS parameters The EHNS parameters have already been constrained by CPLEAR results  = ( 0.5 ± 2.8) x 1017 GeV  = ( 2.5 ± 2.3) x 1019 GeV  = ( 1.1 ± 2.5) x 1021 GeV KLOE can reach equal sensitivity on , with present data sample just with the ++ channel F. Bossi, CSN1, Frascati 14 Ottobre 2005

15. Fixing the EHNS parameters With 20 fb1one can dramatically improve, especially onand In the plots below the horizontal line is CPLEAR, VDETmeansvert=¼ S (/S) (/S) (/S) • Present KLOE •KLOE + VDET fb1 fb1 fb1 F. Bossi, CSN1, Frascati 14 Ottobre 2005

16. CPT and Bose statistics: the BMP model Bernabeu, Mavromatos and Pavassiliou argued that in presence of CPT violation induced by quantum gravity the concept of antiparticle has to be modified. In this case the KSKLstate from  decays does not strictly obeyBose statistics, thus modifying the final state wave function І i > = C {( ІKS(+)> ІKL()>  ІKL(+)>ІKS()>) +  ( ІKS(+)> ІKS()>  ІKL(+)>ІKL()>)} The complex parameter  quantifies the departure from Bose statistics, in a formalism in which the time evolution of the stateis still described by the equationsof standard QM Naively, ІІ~ O(MK2 / MPlank )1/2 ~ 10-3  104 F. Bossi, CSN1, Frascati 14 Ottobre 2005

17. Measuring the  parameter The parameter  can be measured by a fit to the decay time distribution of the KSKL pair to 4 Arg() = 0, ІІ = 1,2,3 x 103 • Present KLOE  • KLOE + VDET A. Di Domenico t (S units) A. Di Domenico fb1 F. Bossi, CSN1, Frascati 14 Ottobre 2005

18. A note on the previous slides All our estimates refer to the ++channel only. Further information can be obtained by other decay channels, to be studied in more detail. F. Bossi, CSN1, Frascati 14 Ottobre 2005

19. Some fundamental bibliography • Hawking, PR D14 (1975) 2460, Comm. Math. Phys. 87 (1982) 395 • Wald, PR D14 (1975) 2460, Comm. Math. Phys. 87 (1982) 395 • Ellis et. al, NP B241 (1984) 381; MPL A10 (1995) 425; PRD53 (1996) 3846 • Huet, Peskin, NP B434 (1995) 3 • Bernabeu, et al. PRL 92 (2004) 131601, hep-ph/0506025 • Benatti, Floreanini, NP B511 (1998) 550 • Bertlmann, Durstberger, Hiesmayr, PR A68 (2003) 012111 F. Bossi, CSN1, Frascati 14 Ottobre 2005

20. Chiral Perturbation Theory F. Bossi, CSN1, Frascati 14 Ottobre 2005

21. ChiralPerturbation Theory In the limit in which u,d,s are massless the QCD lagrangian is invariant under SUL(3)xSUR(3). The left-handed world is separate from the right-handed one: this is chiral symmetry. The dynamical breaking of this (approximate) symmetry produces 8 massless Goldstone bosons to be identified with the , K,  One then writes down the most general lagrangian consistent with the chiral symmetry, and expands it in terms of the momentum of the involved particles. If momenta are low enough, then: M(p2) > M(p4) > M(p6) … …and one can perform calculations perturbatively This is the basic idea of Chiral Perturbation Theory F. Bossi, CSN1, Frascati 14 Ottobre 2005

22. ChPT: the pros and the cons Thus chiral symmetry is: • A true/direct consequence of QCD • A rigorous way to calculate in the low energy region On the other hand, the effective ChPT lagrangian leaves a number of free parameters to be determined experimentally, that increase with the order to which the lagrangian is computed Thus, the higher you go with the power of p, the higher is the number of the number measurement you need to fix the theory 2 at orderd p2, 12 at order p4… F. Bossi, CSN1, Frascati 14 Ottobre 2005

23. KS  : a test for ChPT NA48/1 has measured BR(KS  ) = (2.78 ±0.06±0.04)x106 This result differs from predictions of ChPT at O(p4) by 30% A preliminary analysis shows that KLOE can reach a statistical accuracy of ~ 4%with the present data sample. A projection to 20 fb1 would give an accuracy better than 1% F. Bossi, CSN1, Frascati 14 Ottobre 2005

24. KS + 0: another test for ChPT ChPT predicts B(Ks  +0) = (2.4 ± 0.7)x107 The present experimental value (3.3 +1.10.9 ) x107 is the average of three different measurement each individually precise at ~ 40% A preliminary KLOE analysis obtains sig~ 1.3%,S/B ~ 2 F. Bossi, CSN1, Frascati 14 Ottobre 2005

25. KS + 0as a pedagogical example This is the typical case where analysis would greatly benefit from simple detector upgrades At least one of the two tracks has low momentum: 65% of signal lost only due to acceptance Acceptance can be increased by the use of a lower B field. Also the use of a vertex chamber could definitely help Both can be useful also for the rejection of the background due to pathological charged kaon events F. Bossi, CSN1, Frascati 14 Ottobre 2005

26. Study of KS +  spectrum Spectrum is distorted wrt to pure I.B. Calculations at O(p4) can lead either to an excess or to a lack of events wrt prediction at O(p2), BR O(106) Toy MC fit: sensitivity to BR at 106 level with 106 events with E > 20MeV Events with 20 fb1: 107 with E > 20 MeV F. Bossi, CSN1, Frascati 14 Ottobre 2005

27. A digression in theworld It is known that a good -factory is also a reasonable -factory. Actually, at present KLOE has the largest  statistics in the world The  world is largely complementary with the K one in that it addresses most of the same physics issues. More on C. Bini’s talk F. Bossi, CSN1, Frascati 14 Ottobre 2005

28. Predictions of the SM F. Bossi, CSN1, Frascati 14 Ottobre 2005

29. KS 0 00: a genuine CP violating decay MC Eff. Stat. = 5.3 data This decay violates CP. SM branching ratio is 2x109 22 Analysis based on  counting and kinematic fit on 20and 30 hypothesis 23 450 pb-1 ’01+’02 data KLOE with 450 pb1 22 B(KS  30) < 1.2 x 107 90% CL based on 2 observed events with an expected background of 3.1 23 F. Bossi, CSN1, Frascati 14 Ottobre 2005

30. KS 0 00: perspectives Background mostly due to photon clusters double splittings Preliminary studies show that there is room for “algorithmic” improvements in background rejection without losses in signal efficiency Study of the entire KLOE data set crucial for a better assessment of the real potentialities of the analysis but… …there are hints that @ 20 fb1 one can reach ~ 5 x 109 With KLOE as it is now. Can we do better than that? see later discussion F. Bossi, CSN1, Frascati 14 Ottobre 2005

31. KS e decays and theS = Q rule The relevant parameter here is: <e+ | Hwk | K0 > ~ 106 S.M. Re (x+)~ <e+ | Hwk | K0 > S 1 + 4 Re(x+) = = Present Uncertainties L 20 103 6 103 BR(KS e) L = BR(KL e) S 1 103 4 103 These are KLOE measurements @ 20 fb1 one can reach ~ 2 103 in BR(KS  e) F. Bossi, CSN1, Frascati 14 Ottobre 2005

32. Play the same game with muons Muon semilptonic channel is more difficult: • Lower expected BR ~ 4 x 104 • High pollution from  events with  decays in flight • More difficult to separate charge states However, it has never been measured before • 2002 data • MCm+p- n • MC ppg • MC pp KLOE has already a clear signal and can reach 3% accuracy with present data This channel clearly begs for more luminosity Emiss Pmiss ( hyp) (MeV) F. Bossi, CSN1, Frascati 14 Ottobre 2005

33. R = (K±  e± ) / (K±  ± ) and new physics This ratio is a sensitive probe for new physics effects (see G. Isidori’s talk) Standard Model Prediction: R = (2.472 ±0.001) x 105 NA48/2 Preliminary 05: R = (2.416 ±0.049) x 105 NA48/2 can reach ~1%precision with present data Scaling from measured efficiencies for Ke3 decays KLOE can aim at ~ 0.5% @ 20 fb1 Use of a vertex chamber could greatly improve efficiency F. Bossi, CSN1, Frascati 14 Ottobre 2005

34. Detector Issues F. Bossi, CSN1, Frascati 14 Ottobre 2005

35. The ingredients of KLOE success E.M: Calorimeter: Drift Chamber: Good momentum resolution Full angular coverage Exceptional timing capabilities Large tracking volume Large lever arm Minimization of materials Excellent e/ separation based on t.o.f. Good 0 reconstruction capabilities Full kinematical reconstruction of events Maximization of efficiency for long-lived particles (K± ,KL) F. Bossi, CSN1, Frascati 14 Ottobre 2005

36. There can be improvements Still, based on our experience, some possible modifications can improve KLOE performance • Use of a lower magnetic field. This can increase acceptance for several of the above mentioned channels and ease pattern recognition • Insertion of a vertex chamber. At present, first tracking layer is at 30 cm (i.e. 50 S) from the I.P. • Try some z coordinate reconstruction in the drift chamber. Pattern recognition would benefit of it. • Increase calorimeter’s readout granularity. Can improve photon counting, as well as particle identification. F. Bossi, CSN1, Frascati 14 Ottobre 2005

37. An explicative example from K+K Split track, no VTX reconstructed Split track F. Bossi, CSN1, Frascati 15 Ottobre 2005

38. Summary (I) A high luminosity factory is a perfect tool to study a wide variety of relevant physics topics in several distinct and complementary ways With KLOE we have learned a lot on how to perform these measurements and have solid ideas on the potentialities of our detector We have also several ideas on the potential improvements that can be done and intend to study in detail the feasibility and relevance of all of them in the coming months F. Bossi, CSN1, Frascati 14 Ottobre 2005

39. Summary (II) Upgrades of the detector can likely be of importance for other important studies, which I did not mention previously because of lack of time and/or because real potentialities have to be understood yet: KS 0e+e (0+) KS 0  KS e+e (+) KL  KSlifetime Improved Vus measurement F. Bossi, CSN1, Frascati 14 Ottobre 2005