Theoretical and Experimental Constraints on Z2n Multi-Component Dark Matter Models
Abstract
A complete assessment of any dark matter model requires confronting its low-energy phenomenology with its high-scale theoretical viability. We undertake such a dual analysis for a class of two-component scalar dark matter models stabilized by Z2n symmetries, specifically the Z4, Z6(23), and Z6(13) frameworks. Each model is tested against the latest observational data, including the Planck relic abundance and stringent direct detection limits from the LUX-ZEPLIN (LZ) experiment. Simultaneously, we evaluate their theoretical integrity up to the GUT and Planck scales by enforcing vacuum stability and perturbative unitarity with one-loop Renormalization Group Equations. This combined approach reveals a rich and varied landscape of possibilities. We demonstrate that the Z4 model offers a broadly viable parameter space sustained by efficient semi-annihilation. In stark contrast, the Z6(13) scenario is shown to be highly fine-tuned, with solutions confined to the Higgs resonance. Our most significant finding concerns the Z6(23) model: we show that an apparent conflict between experimental data and high-scale consistency is resolved when the model is viewed as an effective field theory, yielding a concrete prediction for new physics at or below the 106 GeV scale. This work provides a definitive guide to the viability of these Z2n scenarios and serves as a compelling demonstration of how high-energy consistency checks can yield crucial insights into the nature of dark matter.
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