Minimal nonsupersymmetricSO(10)model: Gauge coupling unification, proton decay, and fermion masses

Abstract: We present a minimal renormalizable non-supersymmetric SO(10) grand unified model with a symmetry breaking sector consisting of Higgs fields in the 54 H + 126 H + 10 H representations. This model admits a single intermediate scale associated with Pati-Salam symmetry along with a discrete parity. Spontaneous symmetry breaking, the unification of gauge couplings and proton lifetime estimates are studied in detail in this framework. Including threshold corrections self-consistently, obtained from a full analysis … Show more

“…1 In fact, it is well established that GUTs based on the gauge group SO(10) [17,18] may solve the fundamental problems i)-iv) discussed above exploiting the same mechanisms as our bottom-up variant of SMASH [19][20][21][22][23][24]. In fact, the right-handed neutrinos and thus the seesaw mechanism and the possibility of baryogenesis via thermal leptogenesis [25] occur automatically in these models.…”

“…a 45 H , also charged under the PQ symmetry [21,23]. A third way is to introduce an SO(10) singlet complex scalar field responsible for the U(1) PQ symmetry breaking [24]. We will consider in this paper benchmark models from all these three categories.…”

“…According to the latter, scalars get masses of the order of their VEVs, so that the scalars remaining active in the RG at a given scale are those whose VEVs lie below that scale. We consider however an exception [24,33]: in order to have a 2HDM at low energies, we will assume that Σ u and Σ d , the SM doublets in the (15, 2, 2) P S of the 126 H , have masses of the order of M BL . Such a choice is not arbitrary.…”

“…where 24) with f PQ andN k determined from the VEVs and PQ charges as in equations (3.18) and (3.21). As anticipated earlier, the θ k parameter for a given group (see (3.1)) and the axion enter the low-energy Lagrangian in the combination θ k + 1/f A,k A.…”

Axion predictions in SO(10) × U(1)PQ models

“…1 In fact, it is well established that GUTs based on the gauge group SO(10) [17,18] may solve the fundamental problems i)-iv) discussed above exploiting the same mechanisms as our bottom-up variant of SMASH [19][20][21][22][23][24]. In fact, the right-handed neutrinos and thus the seesaw mechanism and the possibility of baryogenesis via thermal leptogenesis [25] occur automatically in these models.…”

“…a 45 H , also charged under the PQ symmetry [21,23]. A third way is to introduce an SO(10) singlet complex scalar field responsible for the U(1) PQ symmetry breaking [24]. We will consider in this paper benchmark models from all these three categories.…”

“…According to the latter, scalars get masses of the order of their VEVs, so that the scalars remaining active in the RG at a given scale are those whose VEVs lie below that scale. We consider however an exception [24,33]: in order to have a 2HDM at low energies, we will assume that Σ u and Σ d , the SM doublets in the (15, 2, 2) P S of the 126 H , have masses of the order of M BL . Such a choice is not arbitrary.…”

“…where 24) with f PQ andN k determined from the VEVs and PQ charges as in equations (3.18) and (3.21). As anticipated earlier, the θ k parameter for a given group (see (3.1)) and the axion enter the low-energy Lagrangian in the combination θ k + 1/f A,k A.…”

Axion predictions in SO(10) × U(1)PQ models

“…Majorana mass terms of right-handed neutrinos can be generated at an intermediate scale, which may explain the smallness of neutrino masses. These interesting aspects have stimulated many extensive studies of SO(10) GUTs [15][16][17][18][19][20][21][22].…”

The ATLAS diboson resonance in non-supersymmetric SO(10)

Yukawa sector of minimal SO(10) unification