arXiv:0706.3931v1 [hep-ph] 26 Jun 2007 ASnmes 21.t 26.n 12.60.Fr 12.60.Cn, 12.10.Kt, numbers: PACS scale. ecnfidtemxn nl eain tdffrn nrylevel energy different at relations angle mixing the find by can leptons, we and quarks known of numbers quantum e lepton unification minus grand at constants coupling the among relation n lcrwa symmetries electroweak and † ∗ lcrncades alexeb@ifi.unicamp.br address: Electronic hswr a upre yFPS P 04/13770-0). (PD FAPESP by supported was work This eitouetesqec fsotnossmer breaking symmetry spontaneous of sequence the introduce We h opigcntnsfra lcrwa oe iha with model electroweak an for constants coupling The eateto omcRy n hoooy tt University State Chronology, and Rays Cosmic of Department SU OBx66,10390 apns P Brazil. SP, Campinas, 13083-970, 6165, Box PO (4) S P SU ⊗ (4) SU S P Dtd uut7 2021) 7, August (Dated: ⊗ (4) .E Bernardini E. A. SU (4) EW Abstract EW 1 nfiainsymmetry unification nodrt sals ahmtclyconsistent mathematically a establish to order in eg cl.Wt h auso barion of values the With scale. nergy pt h electromagnetic the to up s nldn ih-addneutrinos, right-handed including faculn ewe Pati-Salam between coupling a of † fCampinas, of ∗ U (1) EM In the context of grand unification theories (GUTs) [1, 2, 3], the necessity of going beyond the (SM) has been established on discussions about gauge coupling unification and oscillation [4] as well as on leptogenesis and certain intriguing features of quark-lepton masses and mixing [5]. so that a detailed study of the has been emphasized and some interesting classes of models have been proposed [6, 7, 8, 9, 10, 11, 12, 15]. An extensive class of models has described an electroweak unification

scheme by using a gauge structure with SU(4)L [14] and SU(3)L [13, 15] symmetries. Such models introduce some multiplet representations which allow the existence of quarks and leptons with exotic charges and, in particular, for some of them, the right-handed appear in the same representation of these new exotic particles. By following a similar development, in the place of a SU(5) unification group, we suggest the coupling between the Pati-Salam (PS) SU(4) symmetry and a left-right electroweak (EW) SU(4) symmetry described by

SU(4) SU(4) PS ⊗ EW g4 g4

φ15 dim , (1) ⇓ − SU(3)c SU(4)EW U(1)B l ⊗ ⊗ − gc g4 gB l − which could be embedded in a higher symmetry and, therefore, make us able to find a relation between the g4 and the gB l coupling constants. As a first analysis, we have supposed that − a designated by a 15 dim representation of SU(4) leads to the spontaneous − PS symmetry breaking (SSB) of SU(4)PS into SU(3)c U(1)B l where the color number is ⊗ − represented by c and the barion minus lepton number by B l. By including the first − generation of the model in the following matrix representation,

e u1L u2L u3L νL

 d1L d2L d3L eL  Ψ= . (2)  u u u νe   1R 2R 3R R     d d d e   1R 2R 3R R    and assuming a universal coupling constant gG in a way that we can establish

G SU(4) SU(4) , (3) ⊃ PS ⊗ EW

2 we can express the the free Lagrangian as

µ = Tr Ψγ DµΨ + coupling and interactions, (4) L with   a a b b DµΨ= ∂ Ψ ig h H Ψ+ h ΨH (5) µ − G µ(EW ) µ(PS) where Ha and Hb are the SU(4) generators for, respectively, EW and PS interactions, which are not exactly in the same irreducible representation. The above assumptions allow us to establish a consistent relation among coupling constants at grand unification energy scale that could be extended to phenomenological constraints at electroweak scale.

To analyze all the possibilities of SSB relative to the SU(4)EW symmetry, we analyze three cases with a minimum number of Higgs bosons[17] necessary to obtain the final

electromagnetic symmetry U(1)EM

Case 1

SU(4)EW U(1)B l ⊗ − g4 gB l − χ ⇓ 4 SU(3) U(1) L(R) ⊗ YSU(3)

g3 gYSU(3) χ . (6) ⇓ 3 SU(2) U(1) L ⊗ Y g g′ ρ, η ⇓ U(1)EM e where χ are n dim multiplets and ρ and η are Higgs doublets which provide the successive n − SSB. We can obtain the neutral Hermitian gauge boson mass matrix M2 written in the W basis of SU(4)EW diagonal generators

1 2 ∆ = W† M W, (7) Lmass 2 · · with

3 8 15 W† = hµ hµ hµ dµ , (8)   3 and H = 1 diag [1, 1, 0, 0] , 3 2 −

H = 1 diag [1, 1, 2, 0] , (9) 8 2√3 −

H = 1 diag [1, 1, 1, 3] . 15 2√6 −

The gauge bosons which carry the quantum numbers of the U(1)EM , U(1)Y and U(1)YSU(3) symmetries are calculated and represented respectively by

1 3 t 8 2 15 Aµ = t h h t h + dµ , (10) 2 µ µ µ √1+2t ∓ √3 ± r3 !

1 t 8 2 15 Bµ = h t h + dµ , (11) 2 µ µ √1+ t ∓√3 ± r3 !

3 2 BSU(3) = t h15 + d , (12) µ t2 µ µ r3+2 ± r3 ! where dµ is the gauge boson related to the U(1)B l symmetry and the parameter t is defined − as t = gB−l . In this way, the relation among t and the mixing angles can be established by g4

sin θ = t cos θ = 1+t2 , w √1+2t2 w 1+2t2 sin θ = t cos θ = q 3+2t2 , (13) 3 − √3+3t2 3 3+3t2 2t2 q 3 sin θ4 = 3+2t2 cos θ4 = 3+2t2 , q q

4 Case 2

SU(4)EW U(1)B l ⊗ − g4 gB l − Φ ⇓ 15 SU(2)L SU(2)R U(1)B l( U(1)EW ) ⊗ ⊗ − ⊗ gL gL gB l − Φ . (14) ⇓ 8 SU(2) U(1) ( U(1) ) L ⊗ Y ⊗ EW g g′ ρ ⇓ U(1)EM e where Φ are n dim multiplets and ρ is a Higgs doublet which provide another sequence n − of successive SSB. We can obtain, again, the neutral Hermitian gauge boson mass matrix 2 M , but now, written in another W basis of diagonal generators of SU(4)EW ,

H = 1 diag [1, 1, 0, 0] , 3 2 −

H = 1 diag [0, 0, 1, 1] , (15) 8 2 −

H = 1 diag [1, 1, 1, 1] . 15 2√2 − −

The gauge bosons related to the U(1)EM and U(1)Y symmetries are respectively

1 3 8 Aµ = t h + t h + dµ , (16) √1+2t2 µ µ 

1 8 Bµ = t h + dµ . (17) √1+ t2 µ  In this case, the relation among the parameter t and the mixing angles can be given by

t 1+t2 sin θw = cos θw = 2 , √1+2t2 1+2t (18) sin θ = t cos θ = q1 , R √1+t2 R √1+t2

5 Case 3

SU(4)EW U(1)B l ⊗ − g4 gB l − Φ ⇓ 8 SU(2)L U(1)Y ( U(1)EW ) ⊗ ⊗ . (19) g g′ ρ ⇓ U(1)EM e Here we immediately notice a simplification of the second case where the same mixing angle relations can be reproduced. At this point, it is pertinent to observe that the U(1) symmetry that appears after the SSB of SU(4) SU(4) carries the B l quantum PS ⊗ EW − numbers which provide the correct values for the electric charge Q quantum numbers to all fermions and bosons. The three cases suggest the possibility of obtaining mixing angle values by introducing a numerical value for t. Proceeding with the unification analysis, independently of the interactions or symmetry breaking mechanisms, the set of generators τ a of a unification symmetry (group) must agree with the following trace relation

Tr[τ aτ b]= Cδab, (20) where C has the same value for each subgroup even depending on the representation over which the traces are taken. To exemplify this point for the above cases, let us observe that the kinetic term (21) related to the Pati-Salam symmetry can be written as

∆ = ψa γµD ψa , (21) Lkinetic PS µ PS i with the left (right) chiral spinor fields ψPS represented by

ur dr

1(3)  ug  2(4)  dg  ψPS = and ψPS = , (22)  u   d   b   b       νe   e   L(R)  L(R)     where r, g and b are the color index. The Pati-Salam covariant derivative thus given by

D = ∂ ig ha Ha, (23) µ µ − 4 µ(PS) 6 which after a SSB provided by a 15 dim Higgs boson becomes − b 14 b λ B l a a Dµ = ∂µ igcGµ igB ldµ − ig4 (hµH ), (24) − 2 − − 2 − i=9 X a where Gµ are related to the massless gluons of SU(3)c, dµ is related to the massless gauge

boson that keeps the hypercharge invariance B l of U(1)B l. and last term could be − − rewritten in terms of the mass eigenstates which appears after SSB. Turning back to the Eq. (20) and taking the 4 dim multiplet ψi of Eq. (22), we obtain − PS 2 2 1 2 (25) Tr[g4Ha ] = 2 g4,

when we consider the normalized generators Ha of SU(4)PS. By the same way,

2 2 1 1 1 1 2 (26) Tr[g(c)λa] = 2 2 +0+ 2 +0 = 2 gc ,   when it is applied to the normalized generators λa of SU(3)c and summed over a color triplet (quarks) and a color singlet (lepton). Finally,

2 B l 2 1 1 1 1 1 2 (27) Tr[gB l 2− ] = 4 9 + 9 + 9 +1 = 3 gB l, − −    which is constructed in terms of the hypercharge of U(1)B l summed over three quarks and − one lepton. Once we have previously assumed

GUnif = g4 = g3 = gL = gR, (28) we are now in position to determine the relation between g4 and g or g′. From Eq. (20) we may write 2 g4 = gc = gB l. (29) r3 − 2 and, by summarizing the above procedure, when we make t = 3 in agreement with the last equality, the mixing angles and the coupling constant relationsq can be written as

3 5 3 sθw = 8 cθw = 8 g′ = 5 g q1 q2 q1 sθ3 = cθ3 = gYSU = g3 √5 √5 (3) 2 (30) √2 √2 3 sθ4 = cθ4 = gB l = g4 − 2 2 − 2 3 2 3 sθR = cθR = gB l = q gR 5 5 − 2 q q q where sθ sin θ and cθ cos θ. Obviously, the electroweak mixing angle θ has the ≡ ≡ w same value in all the three cases and corresponds to one of few experimental concordant

7 results generated by the SU(5) model [16]. Furthermore, the model concerns about the existence of a right-handed neutrino as a fundamental lepton so that the discussion about anomaly cancellation is unnecessary since, for each fermion generation, a left-right symmetry is assumed. All the elements are constructed without introducing any exotic character and, with some phenomenological analysis, these results could be extended to the study of gauge boson mass generation and neutral and charged vector currents.

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