Gravitational production of superheavy dark matter and associated cosmological signatures

Primordial non-Gaussianity signatures of extremely heavy particles are reexamined within a simple alternative to the standard inflationary paradigm, in which the primordial fluctuations and the inflationary spacetime expansion are sourced by two different fields. The curvaton scenario provides an example of this in which the distinct roles are played by the curvaton and the inflaton fields, respectively. We study couplings of the curvaton to heavy particles with masses of order the inflationary Hubble scale, and show that they can lead to non-Gaussian signals orders of magnitude larger than those in standard inflation, consistent with explicit effective field theory control of inflationary dynamics. This brings various motivated particle physics signatures, such as loops of heavy gauge-charged scalars and fermions, within future observational reach. The curvaton paradigm can be viewed as a partial UV completion of effective field theories of only inflationary fluctuations in which large non-Gaussian signals of heavy particles have also been discussed, but in which inflationary dynamics is not explicitly derived.

Section: Introductionmentioning

confidence: 99%

Cosmological collider physics and the curvaton

Kumar

Sundrum

2020

“…Additionally, the subscript (2) denotes the number of interaction vertices. This type of integral in the squeezed limit k 1 k 2 k 3 is well-known [17,50,53,60,103] and the details are collected in appendix. A. Eq.…”

Section: Bispectrummentioning

confidence: 96%

“…From the frequency of the oscillation on the squeezed limit non-Gaussianity, one can directly obtain information about the mass of extra fields during inflation. We investigated the search for the dark matter mass in the context of cosmological collider physics in [53], targeting at the class known as superheavy dark matter (SHDM) [69][70][71][72][73][74] with mass m σ ≥ H. 1 Since the dark matter is produced gravitationally, the signal is subject to a suppression of power (H/M pl ), which makes it hardly observable in the near future experiments.…”

Section: Jhep07(2020)231mentioning

confidence: 99%

“…As discussed before, without further interactions σ is then a massive stable particle and interacting with other fields via the small coupling and χ as the mediator, making itself a good DM candidate. For its gravitational production during inflation, we will mostly follow the calculations in [53]. Note that we are interested in the case where the mediator field χ is a light field, i.e., m 2…”

Section: Jhep07(2020)231mentioning

confidence: 99%

“…which is constant in time. Assuming matter domination before reheating and radiation domination afterwards, the current DM abundance can be expressed numerically [53,73]:…”

Section: Jhep07(2020)231mentioning

confidence: 99%

See 2 more Smart Citations

Cosmological signatures of superheavy dark matter

Wang

et al. 2020

Self Cite

We discuss two possible scenarios, namely the curvaton mechanism and the dark matter density modulation, where non-Gaussianity signals of superheavy dark matter produced by gravity can be enhanced and observed. In both scenarios, superheavy dark matter couples to an additional light field as a mediator. In the case of derivative coupling, the resulting non-Gaussianities induced by the light field can be large, which can provide inflationary evidences for these superheavy dark matter scenarios.

Jump starting the dark sector with a phase transition

Redi

Tesi

2023

We study the possibility to populate the dark sector through a phase transition. We will consider secluded dark sectors made of gauge theories, Randall-Sundrum scenarios and conformally coupled elementary particles. These sectors have in common the fact that the action is approximately Weyl invariant, implying that particle production due to time dependent background is strongly suppressed. In particular no significant production takes place during inflation allowing to avoid strong isocurvature constraints from CMB. As we will show, if the scale of inflation is large compared to the dynamical mass scale, these sectors automatically undergo a phase transition that in the simplest cases is controlled by the Hubble parameter. If the phase transition takes place during reheating or radiation the abundance obtained can be larger than particle production and production from the SM plasma. For phase transitions completing during radiation domination, the DM mass is predicted in the range 108 GeV while larger values are required for phase transitions occurring during reheating.