Dark-Matter Decay as a Complementary Probe of Multicomponent Dark Sectors

We consider a model of two-component dark matter based on a hidden U (1) D symmetry, in which relic densities of the dark matter are determined by forbidden channels and thermal freeze-out. The hidden U (1) D symmetry is spontaneously broken to a residual Z 4 symmetry, and the lightest Z 4 charged particle can be a dark matter candidate. Moreover, depending on the mass hierarchy in the dark sector, we have two-component dark matter. We show that the relic density of the lighter dark matter component can be determined by forbidden annihilation channels which require larger couplings compared to the normal freeze-out mechanism. As a result, a large self-interaction of the lighter dark matter component can be induced, which may solve small scale problems of ΛCDM model. On the other hand, the heavier dark matter component is produced by normal freeze-out mechanism. We find that interesting implications emerge between the two dark matter components in this framework. We explore detectabilities of these dark matter particles and show some parameter space can be tested by the SHiP experiment.

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“…(19) and (30), respectively. The cross section is very suppressed by the electron Yukawa coupling (the electron mass).…”

Section: Direct Detectionmentioning

confidence: 99%

Implications of two-component dark matter induced by forbidden channels and thermal freeze-out

Aoki

Toma

2017

J. Cosmol. Astropart. Phys.

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“…Off-diagonal dark-matter scenarios exhibit a rich set of complementarity relations [3]. Indeed, as discussed in the Introduction and in Ref.…”

Section: Rates and Cross Sectionsmentioning

confidence: 97%

“…In multicomponent dark-matter scenarios, however, the experimental complementarity picture can be even richer and more subtle than it is in traditional, single-component scenarios [3]. One reason is that the multicomponent nature of the dark sector allows for two distinct classes of processes which can generically contribute to the relevant experimental event rates.…”

Section: Introductionmentioning

confidence: 99%

“…These processes include the inelastic scattering of dark matter with visible matter, dark-matter co-annihilation, and asymmetric pair-production processes at colliders. Moreover, this latter class also includes a wholly different type of process that has no analogue in single-component dark-matter models: the decay of a heavier dark-matter species to a final state comprising a lighter dark-matter species and some number of SM particles [3]. Since the underlying amplitudes associated with dark-matter decay processes are also generally related through crossing symmetries to the amplitudes associated with dark-matter production, scattering, and annihilation, the web of dark-matter complementarity relations in multicomponent dark-matter scenarios is significantly enhanced relative to that which emerges in single-component scenarios.…”

Section: Introductionmentioning

confidence: 99%

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Off-diagonal dark-matter phenomenology: Exploring enhanced complementarity relations in nonminimal dark sectors

2017

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In most multicomponent dark-matter scenarios, two classes of processes generically contribute to event rates at experiments capable of probing the nature of the dark sector. The first class consists of "diagonal" processes involving only a single species of dark-matter particle-processes analogous to those which arise in single-component dark-matter scenarios. By contrast, the second class consists of "off-diagonal" processes involving dark-matter particles of different species. Such processes include inelastic scattering at direct-detection experiments, asymmetric production at colliders, dark-matter co-annihilation, and certain kinds of dark-matter decay. In typical multicomponent scenarios, the contributions from diagonal processes dominate over those from off-diagonal processes. Unfortunately, this tends to mask those features which are most sensitive to the multicomponent nature of the dark sector. In this paper, by contrast, we point out that there exist natural, multicomponent dark-sector scenarios in which the off-diagonal contributions actually dominate over the diagonal. This then gives rise to a new, enhanced picture of dark-matter complementarity. In this paper, we introduce a scenario in which this situation arises and examine the enhanced picture of dark-matter complementarity which emerges.

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“…As such, DDM furnishes what may be considered to be the most general example of a non-minimal dark sector, and even reduces to (and thereby incorporates) the simple case of a single hyperstable dark-matter particle as the number of individual states within the DDM ensemble is taken to one. However, as the number of dark-sector states becomes larger, these ensembles give rise to rich collider-based, astrophysical, and cosmological phenomenologies [3][4][5][6][7][8][9] which generalize and even transcend what is possible with a single dark-matter particle alone.…”

Section: Introductionmentioning

confidence: 99%

Randomness in the dark sector: Emergent mass spectra and Dynamical Dark Matter ensembles

2016

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In general, non-minimal models of the dark sector such as Dynamical Dark Matter posit the existence of an ensemble of individual dark components with differing masses, cosmological abundances, and couplings to the Standard Model. Perhaps the most critical among these features is the spectrum of masses, as this goes a long way towards determining the cosmological abundances and lifetimes of the corresponding states. Many different underlying theoretical structures can be imagined for the dark sector, each giving rise to its own mass spectrum and corresponding density of states. In this paper, by contrast, we investigate the spectrum of masses that emerges statistically from underlying processes which are essentially random. We find a density of states n(m) which decreases as a function of mass and actually has an upper limit mmax beyond which n(m) = 0. We also demonstrate that this "emergent" density of states is particularly auspicious from the perspective of the Dynamical Dark Matter framework, leading to cosmological abundances and decay widths that are suitably balanced against each other across the dark-matter ensemble. Thus randomness in the dark sector coexists quite naturally with Dynamical Dark Matter, and we examine the prospects for observing the signals of such scenarios in dark-matter indirect-detection experiments.

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Dark-Matter Decay as a Complementary Probe of Multicomponent Dark Sectors

Cited by 55 publications

References 64 publications

Implications of two-component dark matter induced by forbidden channels and thermal freeze-out

Implications of two-component dark matter induced by forbidden channels and thermal freeze-out

Off-diagonal dark-matter phenomenology: Exploring enhanced complementarity relations in nonminimal dark sectors

Randomness in the dark sector: Emergent mass spectra and Dynamical Dark Matter ensembles

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