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OU-HET-652/2010 Yukawaon model and unified description of quark and lepton mass matrices1 Yoshio Koide Department of Physics, Osaka University, Toyonaka, Osaka 560-0043, Japan 0 E-mail address: [email protected] 1 0 2 Abstract n In the so-called yukawaon model, where effective Yukawa coupling constants Yeff (f = a f J e,ν,u,d) are given by vacuum expectation values of gauge singlet scalars (yukawaons) Y f 3 with 3 3 flavor components, it is tried to give a unified description of quark and lepton 1 × mass matrices. Especially, without assuming any discrete symmetry in the lepton sector, ] nearly tribimaximal mixing is derived by assumed a simple up-quark mass matrix form. h p - p 1 What is a yukawaon model? e h [ First, let us give a short review of the so-called yukawaon model: We regard Yukawa coupling 1 eff constants Y as effective coupling constants Y in an effective theory, and we consider that v f f 5 Yeff originate in vacuum expectation values (VEVs) of new gauge singlet scalars Y , i.e. f f 7 0 2 y . Yeff = f Y , (1) 1 f Λh fi 0 0 where Λ is a scale of an effective theory which is valid at µ Λ, and we assume Y Λ. f 1 ≤ h i ∼ : We refer the fields Y as yukawaons [1] hereafter. Note that the effective coupling constants v f eff i Y evolve as those in the standard SUSY model below the scale Λ, since a flavor symmetry is X f completely broken at a high energy scale µ Λ. r a ∼ In the present work, we assume an O(3) flavor symmetry. In order to distinguish each Y f from others, we assume a U(1) symmetry (i.e. sector charge). (The SU(2) doublet fields q, ℓ, X L H and H are assigned to sector charges Q = 0.) Then, we obtain VEV relations as follows: u d X (i) We give an O(3) and U(1) invariant superpotential for yukawaons Y . (ii) We solve SUSY X f vacuum conditions ∂W/∂Y = 0. (iii) Then, we obtain VEV relations among Y . f f For example, in the seesaw-type neutrino mass matrix, M Y Y −1 Y T, we obtain ν ν R ν ∝ h ih i h i [2] Y Y Φ + Φ Y (2) R e u u e h i ∝ h ih i h ih i together with Y Y and Y Φ Φ , i.e. a neutrino mass matrix is given by ν e u u u h i ∝ h i h i∝ h ih i −1 M Y Y Φ + Φ Y Y , (3) ν e e e e e u e u e e e e e h i ∝ h i {h i h i h i h i } h i where Φ diag(√m ,√m ,√m ), and A denotes a form of a VEV matrix A in the u u u c t f h i ∝ h i h i diagonal basis of Y (we refer it as f basis). We can obtain a form Φ = V(δ)T Φ V(δ) f u d u u h i h i h i 1 To appear in theProceedings of Lepton-Photon 2009. from the definition of the CKM matrix V(δ), but we do not know an explicit form of Φ . u e h i Therefore, in a previous work [2], the author put an ansatz, Φ = V(π)T Φ V(π) by u e u u h i h i supposing Φ Φ , and he obtained excellent predictions of the neutrino oscillation u e u d h i ≃ h i parameters without assuming any discrete symmetry. However, there is no theoretical ground for the ansatz for the form Φ . u e h i The purpose of the present work is to investigate a quark mass matrix model in order to predict neutrino mixing parameters on the basis of a yukawaon model (2), without such the ad hoc ansatz, because if we give a quark mass matrix model where mass matrices (M ,M ) are u d given on the e basis, then, we can obtain the form Φ by using a transformation Φ = u e u e h i h i U Φ UT, where U is defined by UTM U = Mdiag. uh uiu u u u u u u 2 Yukawaons in the quark sector We assume a superpotential in the quark sector [3]: ξ W = µ [Y Θ ]+λ [Φ Φ Θ ]+µX[Φ ΘX]+µX[Y ΘX]+ q[Φ (Φ +a E)Φ ΘX]. (4) q u u u u u u u u u u d d d X Λ e X q e q q=u,d Here and hereafter, for convenience, we denotes Tr[...] as [....] simply. From SUSY vacuum conditions ∂W/∂Θ =0, ∂W/∂ΘX = 0 and ∂W/∂ΘX = 0, we obtain Y Φ Φ , u u d h ui ∝ h uih ui M1/2 Φ Φ ( Φ +a E ) Φ , (5) u ∝ h uie ∝ h eie h Xie uh ie h eie M Y Φ ( Φ +a E ) Φ , (6) d d e e e X e d e e e ∝ h i ∝ h i h i h i h i respectively. Here, Φ and E are given by X e e h i h i 1 1 1 1 0 0 1    Φ X 1 1 1 , E 1 0 1 0 . (7) X e e h i ∝ ≡ 3  h i ∝ ≡    1 1 1   0 0 1  (Note thattheVEVform ΦX e breaks theO(3) flavor symmetry into S3.) Therefore, weobtain h i quark mass matrices M1/2 M1/2(X +a 1)M1/2, M M1/2 X +a eiαd1 M1/2, (8) u ∝ e u e d ∝ e (cid:0) d (cid:1) e on the e basis. Note that we have assumed that the O(3) relations are valid only on the e and u bases, so that Y and Y must be real. e u h i h i A case au 0.56 can give a reasonable up-quark mass ratios mu1/mu2 = 0.043 and ≃ − p pmu2/mu3 = 0.057, which are in favor of the observed values [4] pmu/mc = 0.045+−00..001130, and m /m = 0.060 0.005 at µ =M . c t Z p ± Sector Parameters Predictions sin2θatm tan2θsolar U13 | | M ξ = +0.0005 0.982 0.449 0.012 ν ξ = 0.0012 0.990 0.441 0.014 − M1/2 a = 0.56 mu = 0.0425 mc = 0.0570 u u − qmc qmt two parameters 5 observables: fitted excellently M a eiαd md, ms, V , V , V , V d d qms qmb | us| | cb| | ub| | td| two parameters 6 observables: not always excellent Table 1: Summary of the present model. 3 Yukawaons in the neutrino However, the up-quark mass matrix (5) failed to give reasonable neutrino oscillation parameter values although it can give reasonable up-quark mass ratios. Therefore, we will slightly modify the model (2) in the neutrino sector. 1/2 Note that the sign of the eigenvalues of M given by Eq.(8) is (+, ,+) for the case u − a 0.56. If we assume that the eigenvalues of Φ must be positive, so that Φ in u u u u u ≃ − h i h i Eq.(2) is replaced as Φ Φ diag(+1, 1,+1), then, we can obtain successful results u u u u h i → h i · − except for tan2θsolar, i.e. predictions sin22θatm = 0.984 and U13 = 0.0128 and an unfavorable | | prediction tan2θ = 0.7033. solar When we introducea new field P with aVEV P diag(+1, 1,+1), we mustconsider u u u h i ∝ − an existence of P Y Φ +Φ Y P in addition to Y P Φ +Φ P Y , because they have the same u e u u e u e u u u u e U(1) charges. Therefore, we modify Eq.(2) into X λ R W = µ [Y Θ ]+ [(Y P Φ +Φ P Y )Θ ]+ξ[(P Y Φ +Φ Y P )Θ ] , (9) R R R R e u u u u e R u e u u e u R Λ { } which leads to VEV relation Y Y P Φ +Φ P Y +ξ(P Y Φ +Φ Y P ). The results at R e u u u u e u e u u e u ∝ a 0.56 are excellently in favor of the observed neutrino oscillation parameters by taking a u ≃ − small value of ξ (see Table 1): | | Also, we can calculate the down-quark sector. We have two parameters (a ,α ) in the d d down-quark sector given in Eq.(8). (See Table 2 in Ref.[3]). The results are roughly reasonable, although Vi3 and V3i are somewhat larger than the observed values. Those discrepancies will | | | | be improved in future version of the model. 4 Summary In conclusion, for the purpose of deriving the observed nearly tribimaximal neutrino mixing, a possible yukawaon model in the quark sector is investigated. Five observable quantities (2 up- quark mass ratios and 3 neutrino mixing parameters) are excellently fitted by two parameters. Also, the CKM mixing parameters and down-quark mass ratios are given under additional 2 parameters. The results are summarized in Table 1. It is worthwhile to notice that the observed tribimaximal mixing in the neutrino sector is substantially obtained from the up-quark mass matrix structure (8). Although the model for down-quark sector still need an improvement, the present approach will provide a new view to a unified description of the masses and mixings. References [1] Y. Koide, Phys.Rev. D78093006 (2008); Phys.Rev.D79 033009 (2009). [2] Y. Koide, Phys.Lett. B665 227 (2008). [3] Y. Koide, Phys.Lett. B680 76 (2009). [4] Z.-z.Xing,H.ZhangandS.Zhou,Phys.Rev.D77(2008) 113016.Also,seeH.FusaokaandY.Koide,Phys. Rev.D57 (1998) 3986.

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