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Physical Program of Tau-charm Factory. V.P.Druzhinin, Budker INP, Novosibirsk. Processes at tau-charm factory. . D s. D. . Main topics. Physics of charmonia Light hadron spectroscopy Open charm hadrons Physics of -lepton. Current and future experiments.
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Physical Program of Tau-charm Factory V.P.Druzhinin, Budker INP, Novosibirsk
Processes at tau-charm factory Ds D
Main topics • Physics of charmonia • Light hadron spectroscopy • Open charm hadrons • Physics of -lepton
Current and future experiments B-Factories produced about 1010 charmed hadrons and 109 -pairs
Charmonium Vector states: J/ 1012 (2S) 1011 (3770) 2109 Higher ’s 108 In decays: c(1S), cJ 1010 hc 108 ((2S)hc0) Comprehensive study of charmonium decays
Charmonium states above open charm threshold • Recently observed new charmonium states: • C+: X(3872), X(3940), Y(3940) , Z(3930) • cJ(2P),c(3S) ? Study of radiative decays of (4040), (4160), (4415). • Search for hadronic transition X,Y,Z • 1--:X(4260),Y(4361),Y(4664) • (e+e- X)50 pb. • Scan of energy region 3.8-5 GeV with integrated luminosity 100 fb-1
Rare J/ decay Number of J/’s 1012 • Weak decays: J/Ds(*)l, Ds*+-, Ds+ B(3-4)10-9 • SM for S=0 weak decays: J/D00, D00 B10-11. Probe for New Physics, FCNC cu transition. • ccss transition with W exchange: C-parity violation decay J/, B10-8 • Search for NP in Lepton Flavor Violation decays J/l+lB(--e+e- ) < 2.7 10-8 (5108 pairs) B(J/+-)< (2-6)10-9 • CP-violation in J/ decays: 3 and more body decays to construct CP-odd observables or 2 body decays with polarization measurement, J/.
Light meson spectroscopy • Low-lying charmonium states decay into light hadrons with relatively small multiplicity • Choosing specific cc-meson decay mode one can study states with practically any quantum numbers • Example: B(J/)=0.5% 5109 tagged mesons. Recently CLEO performed precise measurement of mass and observed decay 3. • Search for glueballs (gg) and hybrids (qqg)
Search for glueballs and hybrids • Lattice QCD predicts glueball spectrum • Glueball states mix with ordinary mesons • Detailed study of the meson properties in different reactions and decay modes • Scalar glueball (f0,a0,K0*) family • J/f0,f0,f0,a0, K*K0* • f0,a0 • For decays into PP,VP,VV,V • Lowest mass hybrid meson has exotic quantum numbers 1-+ • Its mass is expected in the range 1.3-2.2 GeV • Two possible candidates 1(1400), 1(1600) in N1N reaction • S-wave decay c11, P-wave decay J/1
D-mesons Three types of D-mesons: D (cd), D0 (du), Ds (ds) Maximum cross section for D-pair production DJ states can be produced in reactions e+eD(*)DJ with 1 nb (4.3-5 GeV) Tau-charm factory can produce 6109 D-pairs and 109 Ds pairs per year. B-factories 1010 charmed hadrons
Advantages of near threshold production • Particle multiplicity at 3.77 GeV is about two times lower than at 10.6 GeV • Two body production e+e-DD. This allows to use double tag method: • fully reconstruct one D • then either fully reconstruct the other D (absolute branching ratios) • or look for events with one missing particle (leptonic, semileptonic decays) • Coherent production of D pairs allows to use quantum correlations for D-meson mixing and CP violation studies
Leptonic and semileptonic decays Measurement decay constants and form factors. Improve understanding of hadronization mechanisms. Validation of lattice QCD. With improved theoretical input determination Vcs and Vcd. Important for B-physics extracting Vub from semileptonic B decay. Current lattice values: fD=2074 MeV fDs=2413 MeV Experiment (CLEO): fD=2069 MeV fDs=2708 MeV Tau-charm factory can provide measurement of the decay constants with accuracy better than 0.5%.
Semileptonic decays o.5% accuracy of BF 106 events
D-mixing at tau-charm factory • Only time integrated measurements • Study of quantum correlations in e+e-D0D0(0) (C-odd) and e+e-D0D*0D0D0 (C-even) At (3770) RM=(x2+y2)/2 can be measured using the ratios For 109 D-pairs about 150 events will be detected. Sensitivity to RM is about 510-6
D-mixing at C-tau factory Probabilities of inclusive decays are proportional to (1 y). S+ or S- are CP-even or CP-odd final states. For 109 D-pairs sensitivity for y is about 810-4 Fit of the inclusive and exclusive rates for decays of DDbar system into different final states allows to determine x, y, rf and f . Expected sensitivity to mixing parameters: 1 ab-1 at tau-charm factory = 10 ab-1 at Super B-factory
Search for CP-violation Direct CP violation in D decays is expected to be small in SM. For CF and DCS decays direct CP violation requires New Physics. Exception: DKS,L with ACP=3.310-3. For Singly Cabibbo Suppressed (SCS) decays SM CPV could reach 10-3. Best limits: Belle: D0K+K-,+- ACP(K+K-)=(0.430.300.11)% ACP(+-)=(0.430.520.12)% At Tau-charm factory CP asymmetry can be tested with 10-3 sensitivity for many final states. CLEO: D+KS+, KS+0 ACP(KS+)=(-0.61.00.3)% ACP(KS+0)=(0.30.90.3)%
Search for CP-violation CV violation in mixing: With 109 D-pairs about 30 (K+e-)(K+e-) events will be detected. |q/p| can be measured with 6% accuracy. Current value is 0.860.16 Use of quantum correlations: At (3770) : f1 and f2 are CP eigenstates of the same CP-parity. The decay D0D0f1f2 is forbidden by CP-invariance. The rate is proportional to difference CP-breaking parameters for f1 and f2. 109 D pairs 10-3 difference between +- and K+K- final states. Similar approach can be used for final states with different CP-parities in e+e- D0Do reaction.
Search for CP-violation Using quantum correlations allows to separate contributions from direct CPV and CPV in mixing For C-odd D0D0 state CPV in mixing does not contribute to asymmetry, for C-even state it contributes with twice intensity. For multibody final states the analysis of Dalitz plots and T-odd moments distribution can increase sensitivity to CPV effects. Tau-charm factory can provide 10-3 sensitivity for CPV in D-decays
Rare D decay • Flavor Changing Neutral Current (cul+l-) • D0+- SM ~10-12 NP - 10-6 • CDF B< 4.310-7 • DXul+l- SM ~10-6 NP - 10-6 • D0 B(D+++-)< 3.910-6 • CLEO B(D++e+e-)< 7.410-6 • Lepton Flavor Violation NP - 10-6 • BABAR B(D0 +e-) <0.81 10-6 • BABAR B(D++e+-) <1.1 10-5 C-tau factory can provide 10-8 sensitivity
Rare D decay New physics can introduce new particles into loop B10-6 SM: short distance B(cull)~10-8 long distance B(Dll )10-6
-physics • 1010-pairs • B-factories 109 • Super-B ~ 51010 • Special run near threshold • 2E=3.55 GeV, =0.1 nb, N=108 • ’s are produced at rest kinematic constraint for hadronic decay very clean data sample • Non- background measured below threshold
Physical goals • High precision measurement BF and structure function for hadronic decays • e///K lepton universality • s • ms,Vus • Study of Lorentz structure of leptonic decay • Lepton energy spectrum 4 Michel parameters, two depend on polarization • Polarized initial beam • Measured via decay of second :
LFV decays Super-B, 75 ab-1 71010 -pairs • decay • Current best limit: • 4.510-8 by Belle with 5108 • At Y(4S): • ISR background from e+e-+- • Upper Limit 1/L • tau-charm factory with 1010 has similar or better sensitivity
Search of CP-violation in decays • CP-violation new physics, charged Higgs • Two amplitudes with different weak and strong phases • -KS-, ACP=310-3 • -K-0 • Observables • Rate asymmetry: (+f+)-(-f)~sin sin • Modified rate asymmetry ~sin sin • Triple product asymmetry (p1p2)~cos sin • For complete description of matrix element , polarization and direction of should be known • Threshold production – low statistics • Polarization may increase sensitivity by several times
Polarization • Michel parameters • CP-violation in -decays • Increase sensitivity by several times ? • Decrease luminosity ?
Tau-charm physics • Charm • Spectroscopy • (Semi)leptonic decays • Rare decays • Mixing • CP violaton • … • Charmonia • Spectroscopy, BFs • Light hadron spectroscopy • J/ rare decays • … • Tau • Spectral functions, BFs • Lorentz structure • CP violation • LFV decays • … • Charm baryons • BFs • Semileptonic decays • …