2015
DOI: 10.1007/jhep10(2015)193
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Weakly-interacting massive particles in non-supersymmetric SO(10) grand unified models

Abstract: Non-supersymmetric SO(10) grand unified theories provide a framework in which the stability of dark matter is explained while gauge coupling unification is realized. In this work, we systematically study this possibility by classifying weakly interacting dark matter candidates in terms of their quantum numbers of SU(2) L ⊗ U(1) Y , B − L, and SU(2) R . We consider both scalar and fermion candidates. We show that the requirement of a sufficiently high unification scale to ensure a proton lifetime compatible wit… Show more

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Cited by 65 publications
(82 citation statements)
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References 189 publications
(416 reference statements)
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“…This discrete symmetry can arise naturally when a gauge symmetry is spontaneously broken [17][18][19][20][21]. The idea of a discrete remnant symmetry has been recently incorporated in SO(10) GUT models [22][23][24]. We show that the stability of the lightest exotic E 6 fermion can be guaranteed by a remnant discrete symmetry, which is therefore an ideal dark matter candidate.…”
Section: Jhep02(2018)016mentioning
confidence: 88%
“…This discrete symmetry can arise naturally when a gauge symmetry is spontaneously broken [17][18][19][20][21]. The idea of a discrete remnant symmetry has been recently incorporated in SO(10) GUT models [22][23][24]. We show that the stability of the lightest exotic E 6 fermion can be guaranteed by a remnant discrete symmetry, which is therefore an ideal dark matter candidate.…”
Section: Jhep02(2018)016mentioning
confidence: 88%
“…Similar to Model 2.1, this model allows for axions in the post-inflationary DM window. Remarkably, the model features a second potential DM candidate: the lightest stable combination of the additional fermions [93][94][95][96]. Therefore we do not need to insist on the axion being 100% of the observed dark matter and can allow for bigger axion masses (cf.…”
Section: Jhep02(2018)103mentioning
confidence: 99%
“…The dark matter candidate is stabilized by a residual Z 2 symmetry arising after the SO(10) symmetry has been completely broken to the SM gauge symmetries [47][48][49][50][51][52][53][54][55][56][57][58][59]. This residual Z 2 , as it turns out, is equivalent to matter parity [60][61][62][63][64].…”
Section: Jhep02(2016)120mentioning
confidence: 98%
“…This model is obtained in a similar manner to that discussed in ref. [57], except now we allow for two intermediate scales. To obtain these intermediate scales, we need to arrange some Higgs fields to acquire vacuum expectation values (VEVs) in specific directions at particular scales.…”
Section: The Modelmentioning
confidence: 99%
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