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Paper detail

Stealth dark matter confinement transition and gravitational waves

We use non-perturbative lattice calculations to investigate the finite-temperature confinement transition of stealth dark matter, focusing on the regime in which this early-universe transition is first order and would generate a stochastic background of gravitational waves. Stealth dark matter extends the standard model with a new strongly coupled SU(4) gauge sector with four massive fermions in the fundamental representation, producing a stable spin-0 'dark baryon' as a viable composite dark matter candidate. Future searches for stochastic gravitational waves will provide a new way to discover or constrain stealth dark matter, in addition to previously investigated direct-detection and collider experiments. As a first step to enabling this phenomenology, we determine how heavy the dark fermions need to be in order to produce a first-order stealth dark matter confinement transition.

preprint2021arXivOpen access
R. C. BrowerK. CushmanG. T. FlemingA. GasbarroA. HasenfratzX. Y. JinG. D. KribsE. T. NeilJ. C. OsbornC. RebbiE. RinaldiD. SchaichP. VranasO. Witzel
hep-phhep-lat
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R. C. BrowerK. CushmanG. T. FlemingA. GasbarroA. HasenfratzX. Y. JinG. D. KribsE. T. NeilJ. C. OsbornC. RebbiE. RinaldiD. SchaichP. VranasO. Witzel

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