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Principle of Multiple Point Criticality in Multi-Scalar Dark Matter Models

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arxiv 2010.09718 v2 pith:SRR52HVK submitted 2020-10-19 hep-ph

Principle of Multiple Point Criticality in Multi-Scalar Dark Matter Models

classification hep-ph
keywords darkmattermodelspmpcvacuamultipleprincipleallowed
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The principle of multiple point criticality (PMPC), which allowed the prediction of the Higgs boson mass before its discovery, has so far been applied to radiatively generated vacua. If this principle is fundamental, following from some presently unknown underlying physics, the PMPC must apply to all vacua, including the multiple vacua of multi-scalar models dominated by tree-level terms. We first motivate this idea and then exemplify it by applying the PMPC to various realizations of singlet scalar dark matter models. We derive constraints on the dark matter properties from the requirement of degenerate vacua and show that some scalar dark matter models are ruled out by the PMPC, while in others the allowed parameters space is constrained.

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  1. Two Higgs doublet model with a complex singlet scalar and Multi-critical Point Principle

    hep-ph 2026-01 unverdicted novelty 5.0

    A 2HDM extended by a complex singlet uses tree-level MPP to motivate degenerate neutral Higgs masses, yielding viable DM phenomenology and a thermally induced strong first-order electroweak phase transition.