1/2 ( ) 1 * 1 2/3 *2 up charm top -1/3 down strange bottom 6 (ν e, ν µ, ν τ ) -1 (e) (µ) (τ) 6 ( 2 ) 6 6 I II III u d ν e e c s ν µ µ t b ν τ τ (2a) (

Size: px

Start display at page:

Download "1/2 ( ) 1 * 1 2/3 *2 up charm top -1/3 down strange bottom 6 (ν e, ν µ, ν τ ) -1 (e) (µ) (τ) 6 ( 2 ) 6 6 I II III u d ν e e c s ν µ µ t b ν τ τ (2a) ("

かげたつかせ
5 years ago
Views:

1 August 26, GIM : CP

2 1/2 ( ) 1 * 1 2/3 *2 up charm top -1/3 down strange bottom 6 (ν e, ν µ, ν τ ) -1 (e) (µ) (τ) 6 ( 2 ) 6 6 I II III u d ν e e c s ν µ µ t b ν τ τ (2a) (2b) (W ±, Z 0 ) ( ) 1 1 2,3 2 3 * 3 4) 3 * 1 2 ( ) 0 * 2 * 3 I.I.Rabi;

3 Table 1: 1) u d s c b t 3 MeV 6 MeV 120 MeV 1.29 GeV 4.2 GeV 178 GeV ν 1 ν 2 ν 3 e µ τ? ev 0.05 ev MeV MeV 1777 MeV * ** m 2 i j = m2 j m2 i m 2 i j max{m2 i, m2 j } 1: ( ) 2) 3) 3

4 (Hess) ) 200m e ( 6) ) 7) π µ π ( ) π 4

1.3 1947 π 8) π 2: ( ) π + p K 0 + Λ 0, K 0 π + +π, Λ 0 π +p ( ) 2 π + p K 0

5 π 8) π 2: ( ) π + p K 0 + Λ 0, K 0 π + +π, Λ 0 π +p ( ) 2 π + p K 0 + Λ 0, K 0 π + + π, Λ 0 π + p (3) π 10 ( 30cm ) 10mb = cm 2 5

6 (1953) ( ) K +, K 0 S = +1 Λ 0, Σ S = 1 π S=0 (3) * 4 (K +, K 0 ), (Σ +, Σ 0, Σ ) p n 1/2 B 3 I 3 Q Q = I 3 + B + S 2 = I 3 + Y 2 Y ( ) (4) (p, n, Λ 0 ) (IOO) (20% ) ( ) IOO SU(3) IOO 8 ( 8 ) η SU(3) 1/2 8 8 (8-foldway) (p, n, Λ) SU(3) ( ) (u,d,s) ( 1964) * 4 s 6

7 Table 2: u d s I 1/2 1/2 0 I 3 +1/2-1/2 0 S B 1/3 1/3 1/3 Y 1/3 1/3-2/3 Q +2/3-1/3-1/3 (uud) (udd) (uds) π u d ū, d ( ) ( s ) ( MeV) µ e + γ (5) (µ ± e ± + 2ν) 2 2 7

8 3 3: ν e = ν µ µ e + γ { (n = udd) (p = uud) + e + ν)} ν e ( ν e ) (ν µ ) π (π + µ + + ν) ν µ (ν µ + d µ + u) ) 2 (ν e, e ), (ν µ, µ ) e- µ- ( ) (1) (ν, e, µ ) (p, n, Λ) *5 10) (2) ( 1.10) 11) 1.5 u,d,s SU(3) * 6 s d * 5 * 6 QCD SU(3) SU(3) 8

9 2 (u,d) (u,s) (W) (u,d) (u,s) *7 W (N.Cabibbo) d d d = d cos θ c + s sin θ c, sin θ c (6) (u,d ) 2 W ( ) Λ g 4, g 4 cos 2 θ c, g 4 sin 2 θ c 4: (a) µ ν µ + e + ν e (b) d u + e + ν e (c) s u + e + ν e 1.6 GIM Z 0 ( 5) Q 1 = u d = u d cos θ c + s sin θ (7) c * 7 9

10 5: (a) ν µ + e ν µ + e (b) ν µ + u(d) ν µ + u(d) j NC1 Q 1 τ 3 Q 1 ūu d d = ūu cos 2 θ c dd sin 2 θ c ss cos θ c sin θ c ( ds + sd) (8) u, d u, d ū, d 1-3 Z 0 5(b) d s (FCNC=Flavor Changing Neutral Current) K 0 µ µ +, K + π + ν ν ( 6(a)(b)) (Branching Ratio) BR(K 0 µ µ + ) = 7.27 ± (9) BR(K + π + ν ν) = 1.6 ± (10) 1) FCNC 2 d s = U d s = cos θ c sin θ c sin θ c cos θ d c s (11) d d s s s c 1 (u,d ) 2 Q 2 = c s = u s cos θ c d sin θ (12) c 10

11 6: GIM (a) K 0 µ µ (b) K + π + ν ν Z (c) (d) (e) (f) (c) (d) (m u = m c ) 11

12 Q 1 Q 2 j NC2 Q 2 τ 3 Q 2 = cc s s = cc cos 2 θ c ss sin 2 θ c dd + cos θ c sin θ c ( ds + sd) (13) j NC Q 1 τ 3 Q 1 + Q 2 τ 3 Q 2 = ūu + cc dd ss (14) FCNC GIM (Glashow-Illioupoulos- Maiani) FCNC 6(c) (f)) GIM m u = m c (c) (e) (d) (f) GIM u,d,s (1970) c - c 1.7 : J/ψ (= c c) p + p J/ψ + X, J/ψ e e + (15a) e + e + J/ψ e e +, µ + µ, (15b) MeV 4 c c J/ψ J/ψ c c ( ) 12

13 ( ) ( ) b (1977) - (1994) CP 3 (u,d),(c,s),(t,b) 3 3 Q d d s b d = U CKM s b U CKM CKM (Cabibbo-Kobayashi-Maskawa) GIM Q 3 = t u b, Q u = c (17) t 3 2 Q 1 τ 3 Q 1 + Q 2 τ 3 Q 2 + Q 3 τ 3 Q 3 = Q u Q u Q d Q d = Q u Q u Q d U UQ d = Q u Q Q d Q d (18) CKM u,c,t d,s,b u u Q u c = V c (19) t t 13 (16)

14 CKM Q uq d = Q uv UQ d V U U CKM CP - 3 CP K CP π K s CP K L K L ππ CP ( ) CP (1973) u,d,s 3 3 N N N 2 N C 2 = N(N 1)/2 2N 1 (2N-1) N 2 N(N 1) (N 1)(N 2) (2N 1) = (20) 2 2 N 2 CP CP N 3 (1974) (1977) (1994) 3 - CKM CP 14

15 1) 1 λ2 λ Aλ 3 (ρ iη) 2 U CKM = λ 1 λ2 Aλ 2 2 Aλ 3 (1 ρ iη) Aλ (21a) λ = ± , A = 0.80 ± 0.04 (21b) ) ) ρ = (1 λ2 ρ = 0.20 ± 0.09, η = (1 λ2 η = 0.33 ± 0.05 (21c) 2 2 (1975) 1777 MeV τ ν τ + l + ν l, l = e, µ (22a) τ ν τ + ū + d (π, ρ ) (22b) ν e, ν µ (ν τ, τ ) ( MeV ) 3-4 ( ) 1989 LEP e + e + Z 0 eē, µ µ, τ τ, uū, c c, b b, N ν α ν α (23) Z N α=1 ν αν α Z N ± ) Z 4 m z /2 45 GeV Z 15 α=1

7: 3.0, 3.2, 3.4 12) (Ω B = ρ B /ρ c, ρ c = = 1.

16 7: 3.0, 3.2, ) (Ω B = ρ B /ρ c, ρ c = = h 2 g/cm 2 ) ( / ) (2.7 ± 0.6) σ 25% 16

17 4 45 GeV (ν α ) (ν i ) ν α = U αi ν i (24) i MNS( - - ) 11) θ ν e cos θ sin θ ν µ E i p + m2 i 2p sin θ cos θ ν 1 (25) ν 2 ν i (t) >= ν i (0) > e ie it (26) t = 0 ν e t ν µ P(ν e ν µ ) = < ν µ (0) ν e (t) > 2 = 1 2 sin2 2θ[1 cos(e 1 E 2 )t] ( ) sin 2 2θ sin m2 2E L m 2 = m 2 2 m2 1 (27a) (27b) L=ct km m 2 (ev) 2 E GeV ν e ν e P(ν e ν e ) = 1 P(ν e ν µ ) 17

18 3 MNS 1 c 13 s 13 e iδ c 12 s 12 1 U MNS = c 23 s 23 1 s 12 c 12 s 23 c 23 s 13 e iδ c 13 1 e iα e iβ (28a) c i j = cos θ i j, s i j = sin θ i j (28b) 3 CKM θ i j i j δ CP α, β / m ev 2, sin 2 θ (29a) m ev 2, sin 2 θ (29b) 1) 3 sin 2 θ 13 < 0.05 (29c) m 2 13 = m m2 12 m2 23 (30) m(ν i ) 1 ev (31) m li M R m(ν i ) m2 l i M R (32) 18

19 m 2 e << m 2 µ << m 2 τ MNS s c 12 s 13 e 12 iδ 2 U MNS = s 12 c c , s (33) s 12 2 c CKM (21a) CKM MNS 1.11 (Branching Ratio) 1) BR(µ e + γ) < (34a) BR(µ eēe) < (34b) BR(µ + N e + N) < (34c) BR(τ l + γ ; l = e, µ) < (34d) BR(τ l + l l ; l, l = e, µ) < (34e) BR(τ l + m 0 ; m = π, K s, ρ, φ, ) < (34f) (e, µ, τ) (ν e, ν µ, ν τ ) e- µ- τ ( ) 3 ν µ ν e µ e + γ (SUSY=super symmetry) SUSY ( 8 ) SUSY MEG (µ e + γ) PRISM 13) 19

20 8: SUSY SUSY µ R, ẽ R, B0 µ e + γ b s(d) + γ, s(d) + g(= gluon) b B- {B( bd) K ( sd) + γ, K( ss) + η (q q) } QCD ) ( ) J µ A = g ψγ µ γ 5 ψ (35) ( ) ( 9) 20

21 9: Z 0, π 0 2γ f ( ) π 0 2γ ( 1.1 ) Z 0 2γ (Q u + Q d ) + Q ν + Q e = 3 2 ( ) ( 1) = 0 (36) ) 21

22 TeV ( 1.1 ) m t /m u 10 8 m t /m(ν τ ) ) 17) 2) 3) ( ) 18) ( ) 19) 1.14 MNS CP 22

23 (LHC ILC * 8 ) SUSY [1] Review of Particle Physics: Phys. Lett. B592 (2004) [2] H.Fritzsch and Z.Xing: Prog.Part.Nucl.Phys. 45 (2000) 1-81, hep-ph/ [3] S:King: Rept.Prog.Phys. 67 (2004) , hep-ph/ [4] I.I. Rabi, Cited in e.g. R.N. Cahn and G. Goldhaber: The Experimental Foundations of Particle Physics. Cambridge University Press (1989) p.52. [5] C.D.Anderson and S.H.Neddermeyer: Phys. Rev. 51 (1937) 884 [6] G.Araki and S.Tomonaga: Phys. Rev. 58 (1940)90 [7] M.Conversi, E.Pancini, and O.Piccioni: Phys. Rev. 71 (1947) 209 [8] G.D.Rochester and C.C.Butler: Nature 160 (1947)855 [9] G.Danby et al.: Phys. Rev. Lett. 9 (1962) 36 [10] Z.Maki et al.: Prog. Theor. Phys. 23 (1960)1174 [11] Z.Maki,M.Nakagawa and S.Sakata: Prog. Theor. Phys. 28 (1962) 870 [12] D.N. Schramm and M.S. Turner: Rev. Mod. Phys. 70 (1998) 303 [13] MEG: PRISM: [14] S.Adler: Phys. Rev., 177(1969), J.Bell and R.Jackiew: Nuovo Cimento, 51A(1969)47 * 8 LHC (Large Hadron Collider) CERN 16 TeV 2007 ILC(International Linear Collider) 1 TeV 23

24 [15] S.Fredriksson; Proc. of the Fourth Tegernsee Int. Conf. on Particle Physics Beyond the Standard Model, 2004, p. 211, hep-ph/ [16] A.E.Nelson and M.J.Strassler: Phys.Rev. D56 (1997) , hep-ph/ [17] P.H.Frampton, P.Q.Hung and M.Sher: Physics Reports, 330 (2000) , hepph/ [18] G.L.Kane, S.F.King,I.N.R.Peddie and L.Velasco-Sevilla: hep-ph/ [19] E.Witten; Hertz Lectures, Quest for Unification; hep-ph/

7 π L int = gψ(x)ψ(x)φ(x) + (7.4) [ ] p ψ N = n (7.5) π (π +,π 0,π ) ψ (σ, σ, σ )ψ ( A) σ τ ( L int = gψψφ g N τ ) N π * ) (7.6) π π = (π, π, π ) π ±

7 π L int = gψ(x)ψ(x)φ(x) + (7.4) [ ] p ψ N = n (7.5) π (π +,π 0,π ) ψ (σ, σ, σ )ψ ( A) σ τ ( L int = gψψφ g N τ ) N π * ) (7.6) π π = (π, π, π ) π ± 7 7. ( ) SU() SU() 9 ( MeV) p 98.8 π + π 0 n 99.57 9.57 97.4 497.70 δm m 0.4%.% 0.% 0.8% π 9.57 4.96 Σ + Σ 0 Σ 89.6 9.46 K + K 0 49.67 (7.) p p = αp + βn, n n = γp + δn (7.a) [ ] p ψ ψ = Uψ, U = n [ α