2013
DOI: 10.1007/jhep10(2013)176
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Baryogenesis and dark matter with vector-like fermions

Abstract: We show that vector-like fermions can act as the dark matter candidate in the universe whilst also playing a crucial role in electroweak baryogenesis through contributing to the barrier in the one-loop thermal scalar potential. In order for the new fermions to give rise to a strong first order phase transition, we show that one requires rather large Yukawa couplings in the new sector, which are strongly constrained by electroweak precision tests and perturbativity. Strong couplings between the dark matter cand… Show more

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Cited by 24 publications
(21 citation statements)
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“…Refs. [35,36] considers a vector-like lepton generation (including new SU(2) singlets) and the possibility of the electromagnetic charge neutral vector-like lepton being a dark matter candidate. They analyze precision electroweak bounds, modifications to Higgs observables and vacuum stability bounds for this extension.…”
Section: Jhep09(2014)130mentioning
confidence: 99%
“…Refs. [35,36] considers a vector-like lepton generation (including new SU(2) singlets) and the possibility of the electromagnetic charge neutral vector-like lepton being a dark matter candidate. They analyze precision electroweak bounds, modifications to Higgs observables and vacuum stability bounds for this extension.…”
Section: Jhep09(2014)130mentioning
confidence: 99%
“…The same applies for inert higgs extensions of the SM [13] (higher SU(2) representations were considered in [14,15]). However, models with vector-like fermions are able to produce the total DM density and BAU for a wide range of masses [16]. An even more extended higgs sector, say a 2-higgs-doublet model improves further the prospects of this scenario by providing the needed CP phases [17,18].…”
Section: Electroweak Baryogenesismentioning
confidence: 99%
“…With the exception of the fermionic models presented in [9][10][11][12] and models with dynamical Yukawa couplings [13][14][15][16][17], the literature has overwhelmingly concentrated in coupling new scalars to the Higgs in order to induce the strong first order phase transition, mostly because the barrier may be generated with a negative Higgs quartic stabilized by a threshold (H † H) 3 term as in [18], which at tree level may only be generated by integrating out heavy scalars, or because in a large temperature expansion of the Higgs effective potential, scalars contribute to a negative cubic term which induces a barrier, while fermions do not [2]. For a classification of the extensive literature on scalar models see [19].…”
Section: Jhep12(2017)064mentioning
confidence: 99%
“…Up to one-loop, the effective potential is determined by the tree level potential (2.2), plus a zero-temperature and a finite temperature 1-loop contribution. The zero-temperature one-loop contribution is given by 12) JHEP12 (2017)064 where µ is the renormalization scale, all couplings must be interpreted as effective couplings at that scale, and a is an index that runs over all boson and fermion fields obtaining mass from the Higgs mechanism. ξ = 1 for fermions, ξ = 0 for bosons.…”
Section: Jhep12(2017)064mentioning
confidence: 99%