Your search keyword '"Thermal production"' showing total 87 results

1. Non-thermal production of pNGB dark matter and inflation.

Author

Abe, Yoshihiko, Toma, Takashi, and Yoshioka, Koichi

Subjects

*DARK matter, *NAMBU-Goldstone bosons, *SYMMETRY breaking, *INFLATIONARY universe, *STANDARD model (Nuclear physics), *PRICE inflation

Abstract

A pseudo Nambu-Goldstone boson (pNGB) is a natural candidate of dark matter in that it avoids the severe direct detection bounds. We show in this paper that the pNGB has another different and interesting face with a higher symmetry breaking scale. Such large symmetry breaking is motivated by various physics beyond the standard model. In this case, the pNGB interaction is suppressed due to the Nambu-Goldstone property and the freeze-out production does not work even with sufficiently large portal coupling. We then study the pNGB dark matter relic abundance from the out-of-equilibrium production via feeble Higgs portal coupling. Further, a possibility is pursued the symmetry breaking scalar in the pNGB model plays the role of inflaton. The inflaton and dark matter are unified in a single field and the pNGB production from inflaton decay is inevitable. For these non-thermally produced relic abundance of pNGB dark matter and successful inflation, we find that the dark matter mass should be less than a few GeV in the wide range of the reheating temperature and the inflaton mass. [ABSTRACT FROM AUTHOR]

Published

2021

2. Thermal QCD Axions across Thresholds.

Author

D'Eramo, Francesco, Hajkarim, Fazlollah, and Yun, Seokhoon

Subjects

AXIONS, QUANTUM chromodynamics, HIGGS bosons, STANDARD model (Nuclear physics), NUMBERS of species, FERMIONS

Abstract

Thermal axion production in the early universe goes through several mass thresholds, and the resulting rate may change dramatically across them. Focusing on the KSVZ and DFSZ frameworks for the invisible QCD axion, we perform a systematic analysis of thermal production across thresholds and provide smooth results for the rate. The QCD phase transition is an obstacle for both classes of models. For the hadronic KSVZ axion, we also deal with production at temperatures around the mass of the heavy-colored fermion charged under the Peccei-Quinn symmetry. Within the DFSZ framework, standard model fermions are charged under this symmetry, and additional thresholds are the heavy Higgs bosons masses and the electroweak phase transition. We investigate the cosmological implications with a specific focus on axion dark radiation quantified by an effective number of neutrino species and explore the discovery reach of future CMB-S4 surveys. [ABSTRACT FROM AUTHOR]

Published

2021

3. Dark Matter production from relativistic bubble walls.

Author

Azatov, Aleksandr, Vanvlasselaer, Miguel, and Yin, Wen

Subjects

DARK matter, PHASE transitions, ELECTROWEAK interactions

Abstract

In this paper we present a novel mechanism for producing the observed Dark Matter (DM) relic abundance during the First Order Phase Transition (FOPT) in the early universe. We show that the bubble expansion with ultra-relativistic velocities can lead to the abundance of DM particles with masses much larger than the scale of the transition. We study this non-thermal production mechanism in the context of a generic phase transition and the electroweak phase transition. The application of the mechanism to the Higgs portal DM as well as the signal in the Stochastic Gravitational Background are discussed. [ABSTRACT FROM AUTHOR]

Published

2021

4. Cosmic abundances of SIMP dark matter.

Author

Choi, Soo-Min, Lee, Hyun, and Seo, Min-Seok

Subjects

*COSMIC abundances, *DARK matter, *ANNIHILATION reactions, *STANDARD model (Nuclear physics), *METAPHYSICAL cosmology

Abstract

Thermal production of light dark matter with sub-GeV scale mass can be attributed to 3 → 2 self-annihilation processes. We consider the thermal average for annihilation cross sections of dark matter at 3 → 2 and general higher-order interactions. A correct thermal average for initial dark matter particles is important, in particular, for annihilation cross sections with overall velocity dependence and/or resonance poles. We apply our general results to benchmark models for SIMP dark matter and discuss the effects of the resonance pole in determining the relic density. [ABSTRACT FROM AUTHOR]

Published

2017

5. Cosmological relaxation through the dark axion portal.

Author

Domcke, Valerie, Schmitz, Kai, and You, Tevong

Subjects

ELECTROWEAK interactions, AXIONS, STANDARD model (Nuclear physics), FERMIONS, PHOTONS, PRODUCTION standards

Abstract

The dark axion portal is a coupling of an axion-like particle to a dark photon kinetically mixed with the visible photon. We show how this portal, when applied to the relaxion, can lead to cosmological relaxation of the weak scale using dark photon production. The key backreaction mechanism involves the Schwinger effect: as long as electroweak symmetry is unbroken, Schwinger production of massless Standard Model fermions, which carry dark millicharges, suppresses the dark photon production. Once the electroweak symmetry is broken, the fermions acquire mass and the suppression is lifted. An enhanced dark photon dissipation then traps the relaxion at a naturally small weak scale. Our model thus provides a novel link between the phenomenological dark axion portal, dark photons, and the hierarchy problem of the Higgs mass. [ABSTRACT FROM AUTHOR]

Published

2022

6. Electromagnetic signals of inelastic dark matter scattering.

Author

Baryakhtar, Masha, Berlin, Asher, Liu, Hongwan, and Weiner, Neal

Abstract

Light dark sectors in thermal contact with the Standard Model can naturally produce the observed relic dark matter abundance and are the targets of a broad experimental search program. A key light dark sector model is the pseudo-Dirac fermion with a dark photon mediator. The dynamics of the fermionic excited states are often neglected. We consider scenarios in which a nontrivial abundance of excited states is produced and their subsequent de-excitation yields interesting electromagnetic signals in direct detection experiments. We study three mechanisms of populating the excited state: a primordial excited fraction, a component up-scattered in the Sun, and a component up-scattered in the Earth. We find that the fractional abundance of primordial excited states is generically depleted to exponentially small fractions in the early universe. Nonetheless, this abundance can produce observable signals in current dark matter searches. MeV-scale dark matter with thermal cross sections and higher can be probed by down-scattering following excitation in the Sun. Up-scatters of GeV-scale dark matter in the Earth can give rise to signals in current and upcoming terrestrial experiments and X-ray observations. We comment on the possible relevance of these scenarios to the recent excess in XENON1T. [ABSTRACT FROM AUTHOR]

Published

2022

7. Freezing-in a hot bath: resonances, medium effects and phase transitions.

Author

Bringmann, Torsten, Heeba, Saniya, Kahlhoefer, Felix, and Vangsnes, Kristian

Subjects

ELECTROWEAK interactions, PHASE transitions, DARK matter, QUANTUM gases, RESONANCE, QUANTUM statistics

Abstract

Relic density calculations of dark matter freezing out from the primordial plasma have reached a high level of sophistication, with several numerical tools readily available that match the observationally required accuracy. Dark matter production via the freeze-in mechanism, on the other hand, is sensitive to much higher temperatures than in the freeze-out case, implying both technical and computational difficulties when aiming for the same level of precision. We revisit the formulation of freeze-in production in a way that facilitates the inclusion of in-medium corrections like plasma effects and the spin statistics of relativistic quantum gases, as well as the temperature dependence of dark matter production rates induced by the electroweak and strong phase transitions, and we discuss in detail the additional complications arising in the presence of s-channel resonances. We illustrate our approach in the context of Higgs portal models, and provide the most accurate calculation to date of the freeze-in abundance of Scalar Singlet dark matter. We explore in particular the case of small reheating temperatures, for which the couplings implied by the freeze-in mechanism may be testable at the LHC. Together with this article we present a major update 6.3 of DarkSUSY with the added capability of performing general freeze-in calculations, including all complications mentioned above. [ABSTRACT FROM AUTHOR]

Published

2022

8. Warm inflation, neutrinos and dark matter: a minimal extension of the Standard Model.

Author

Levy, Miguel, Rosa, João G., and Ventura, Luís B.

Abstract

We show that warm inflation can be realized within a minimal extension of the Standard Model with three right-handed neutrinos, three complex scalars and a gauged lepton/B-L U(1) symmetry. This simple model can address all the shortcomings of the Standard Model that are not related to fine-tuning, within general relativity, with distinctive experimental signatures that can be probed in the near future. The inflaton field emerges from the collective breaking of the U(1) symmetry, and interacts with two of the right-handed neutrinos, sustaining a high-temperature radiation bath during inflation. The discrete interchange symmetry of the model protects the scalar potential against large thermal corrections and leads to a stable inflaton remnant at late times which can account for dark matter. Consistency of the model and agreement with Cosmic Microwave Background observations naturally yield light neutrino masses below 0.1 eV, while thermal leptogenesis occurs naturally after a smooth exit from inflation into the radiation era. [ABSTRACT FROM AUTHOR]

Published

2021

9. Gravitational waves and dark photon dark matter from axion rotations.

Author

Co, Raymond T., Harigaya, Keisuke, and Pierce, Aaron

Abstract

An axion rotating in field space can produce dark photons in the early universe via tachyonic instability. This explosive particle production creates a background of stochastic gravitational waves that may be visible at pulsar timing arrays or other gravitational wave detectors. This scenario provides a novel history for dark photon dark matter. The dark photons may be warm at a level detectable in future 21-cm line surveys. For a consistent cosmology, the radial direction of the complex field containing the axion must be thermalized. We explore a concrete thermalization mechanism in detail and also demonstrate how this setup can be responsible for the generation of the observed baryon asymmetry. [ABSTRACT FROM AUTHOR]

Published

2021

10. Spontaneously stabilised dark matter from a fermiophobic U(1)′ gauge symmetry.

Author

Fu, B. and King, S.F.

Abstract

We consider the possibility that dark matter is stabilised by a discrete Z2 symmetry which arises from a subgroup of a U(1)′ gauge symmetry, spontaneously broken by integer charged scalars, and under which the chiral quarks and leptons do not carry any charges. A chiral fermion χ with half-integer charge is odd under the preserved Z2, and hence becomes a stable dark matter candidate, being produced through couplings to right-handed neutrinos with vector-like U(1)′ charges, as in the type Ib seesaw mechanism. We calculate the relic abundance in such a low energy effective seesaw model containing few parameters, then consider a high energy renormalisable model with a complete fourth family of vector-like fermions, where the chiral quark and lepton masses arise from a seesaw-like mechanism. With the inclusion of the fourth family, the lightest vector-like quark can contribute to the dark matter production, enlarging the allowed parameter space that we explore. [ABSTRACT FROM AUTHOR]

Published

2021

11. Dark matter interacting via a massive spin-2 mediator in warped extra-dimensions.

Author

de Giorgi, A. and Vogl, S.

Subjects

DARK matter, DARK energy, CENTER of mass, SET theory, WEAKLY interacting massive particles, MANUFACTURING processes

Abstract

We study dark matter interacting via a massive spin-2 mediator. To have a consistent effective theory for the spin-2 particle, we work in a warped extra-dimensional model such that the mediator(s) are the Kaluza-Klein (KK) modes of the 5D graviton. We pay close attention to dark matter annihilations into KK-gravitons. Due to the high energy behavior of longitudinal modes of spin-2 fields, these channels exhibit a tremendous growth at large center of mass energies s if only one spin-2 mediator is considered. For the first time, we include the full KK-tower in this dark matter production process and find that this growth is unphysical and cancels once the full field content of the extra-dimensional theory is taken into account. Interestingly, this implies that it is not possible to approximate the results obtained in the full theory with a reduced set of effective interactions once s is greater than the first graviton mass. This casts some doubt on the universal applicability of previous studies with spin-2 mediators within an EFT framework and prompts us to revisit the phenomenological allowed parameter space of gravitationally interacting scalar dark matter in warped extra-dimensions. [ABSTRACT FROM AUTHOR]

Published

2021

12. Hidden photon and axion dark matter from symmetry breaking.

Author

Nakayama, Kazunori and Yin, Wen

Subjects

AXIONS, DARK matter, SYMMETRY breaking, STANDARD model (Nuclear physics), NAMBU-Goldstone bosons, PHOTONS

Abstract

A light hidden photon or axion-like particle is a good dark matter candidate and they are often associated with the spontaneous breaking of dark global or gauged U(1) symmetry. We consider the dark Higgs dynamics around the phase transition in detail taking account of the portal coupling between the dark Higgs and the Standard Model Higgs as well as various thermal effects. We show that the (would-be) Nambu-Goldstone bosons are efficiently produced via a parametric resonance with the resonance parameter q ∼ 1 at the hidden symmetry breaking. In the simplest setup, which predicts a second order phase transition, this can explain the dark matter abundance for the axion or hidden photon as light as sub eV. Even lighter mass, as predicted by the QCD axion model, can be consistent with dark matter abundance in the case of first order phase transition, in which case the gravitational wave signals may be detectable by future experiments such as LISA and DECIGO. [ABSTRACT FROM AUTHOR]

Published

2021

13. A model for mixed warm and hot right-handed neutrino dark matter.

Author

Dutra, Maíra, Oliveira, Vinícius, de S. Pires, C. A, and Queiroz, Farinaldo S.

Subjects

DARK matter, STERILE neutrinos, NEUTRINOS, POPULATION density, DEGREES of freedom, NUCLEOSYNTHESIS

Abstract

We discuss a model where a mixed warm and hot keV neutrino dark matter rises naturally. We arrange active and sterile neutrinos in the same SU(3)L multiplet, with the lightest sterile neutrino being dark matter. The other two heavy sterile neutrinos, through their out-of-equilibrium decay, contribute both to the dilution of dark matter density and its population, after freeze-out. We show that this model features all ingredients to overcome the overproduction of keV neutrino dark matter, and explore the phenomenological implications for Big Bang Nucleosynthesis and the number of relativistic degrees of freedom. [ABSTRACT FROM AUTHOR]

Published

2021

14. Hidden dark matter from Starobinsky inflation.

Author

Li, Qiang, Moroi, Takeo, Nakayama, Kazunori, and Yin, Wen

Subjects

INFLATIONARY universe, DARK matter, COSMIC background radiation, GRAVITATIONAL interactions, PRICE inflation

Abstract

The Starobinsky inflation model is one of the simplest inflation models that is consistent with the cosmic microwave background observations. In order to explain dark matter of the universe, we consider a minimal extension of the Starobinsky inflation model with introducing the dark sector which communicates with the visible sector only via the gravitational interaction. In Starobinsky inflation model, a sizable amount of dark-sector particle may be produced by the inflaton decay. Thus, a scalar, a fermion or a vector boson in the dark sector may become dark matter. We pay particular attention to the case with dark non-Abelian gauge interaction to make a dark glueball a dark matter candidate. In the minimal setup, we show that it is difficult to explain the observed dark matter abundance without conflicting observational constraints on the coldness and the self-interaction of dark matter. We propose scenarios in which the dark glueball, as well as other dark-sector particles, from the inflaton decay become viable dark matter candidates. We also discuss possibilities to test such scenarios. [ABSTRACT FROM AUTHOR]

Published

2021

15. Efficient numerical integration of thermal interaction rates.

Author

Jackson, G. and Laine, M.

Subjects

NUMERICAL integration, CHEMICAL potential, PHYSICAL cosmology, ALGORITHMS, QUARK-gluon plasma

Abstract

In many problems in particle cosmology, interaction rates are dominated by 2 ↔ 2 scatterings, or get a substantial contribution from them, given that 1 ↔ 2 and 1 ↔ 3 reactions are phase-space suppressed. We describe an algorithm to represent, regularize, and evaluate a class of thermal 2 ↔ 2 and 1 ↔ 3 interaction rates for general momenta, masses, chemical potentials, and helicity projections. A key ingredient is an automated inclusion of virtual corrections to 1 ↔ 2 scatterings, which eliminate logarithmic and double-logarithmic IR divergences from the real 2 ↔ 2 and 1 ↔ 3 processes. We also review thermal and chemical potential induced contributions that require resummation if plasma particles are ultrarelativistic. [ABSTRACT FROM AUTHOR]

Published

2021

16. Testing freeze-in with axial and vector Z′ bosons.

Author

Cosme, Catarina, Dutra, Maíra, Godfrey, Stephen, and Gray, Taylor

Subjects

Z bosons, DARK energy, DARK matter, MAGNETIC moments, WEAKLY interacting massive particles, NEUTRINOS

Abstract

The freeze-in production of Feebly Interacting Massive Particle (FIMP) dark matter in the early universe is an appealing alternative to the well-known — and constrained — Weakly Interacting Massive Particle (WIMP) paradigm. Although challenging, the phenomenology of FIMP dark matter has been receiving growing attention and is possible in a few scenarios. In this work, we contribute to this endeavor by considering a Z′ portal to fermionic dark matter, with the Z′ having both vector and axial couplings and a mass ranging from MeV up to PeV. We evaluate the bounds on both freeze-in and freeze-out from direct detection, atomic parity violation, leptonic anomalous magnetic moments, neutrino-electron scattering, collider, and beam dump experiments. We show that FIMPs can already be tested by most of these experiments in a complementary way, whereas WIMPs are especially viable in the Z′ low mass regime, in addition to the Z′ resonance region. We also discuss the role of the axial couplings of Z′ in our results. We therefore hope to motivate specific realizations of this model in the context of FIMPs, as well as searches for these elusive dark matter candidates. [ABSTRACT FROM AUTHOR]

Published

2021

17. A multi-component SIMP model with U(1)X→ Z2 × Z3.

Author

Choi, Soo-Min, Kim, Jinsu, Ko, Pyungwon, and Li, Jinmian

Subjects

HADRONS, GAUGE symmetries, DARK matter, SYMMETRY breaking

Abstract

Multi-component dark matter scenarios are studied in the model with U(1)X dark gauge symmetry that is broken into its product subgroup Z2 × Z3 á la Krauss-Wilczek mechanism. In this setup, there exist two types of dark matter fields, X and Y, distinguished by different Z2 × Z3 charges. The real and imaginary parts of the Z2-charged field, XR and XI, get different masses from the U(1)X symmetry breaking. The field Y, which is another dark matter candidate due to the unbroken Z3 symmetry, belongs to the Strongly Interacting Massive Particle (SIMP)-type dark matter. Both XI and XR may contribute to Y's 3 → 2 annihilation processes, opening a new class of SIMP models with a local dark gauge symmetry. Depending on the mass difference between XI and XR, we have either two-component or three-component dark matter scenarios. In particular two- or three-component SIMP scenarios can be realised not only for small mass difference between X and Y, but also for large mass hierarchy between them, which is a new and unique feature of the present model. We consider both theoretical and experimental constraints, and present four case studies of the multi-component dark matter scenarios. [ABSTRACT FROM AUTHOR]

Published

2021

18. The axion-baryon coupling in SU(3) heavy baryon chiral perturbation theory.

Author

Vonk, Thomas, Guo, Feng-Kun, and Meißner, Ulf-G.

Subjects

CHIRAL perturbation theory, BARYONS, AXIONS, NUCLEAR matter, NEUTRON stars, HYPERONS, FRAMES (Social sciences)

Abstract

In the past, the axion-nucleon coupling has been calculated in the framework of SU(2) heavy baryon chiral perturbation theory up to third order in the chiral power counting. Here, we extend these earlier studies to the case of heavy baryon chiral perturbation theory with SU(3) flavor symmetry and derive the axion coupling to the full SU(3) baryon octet, showing that the axion also significantly couples to hyperons. As studies on dense nuclear matter suggest the possible existence of hyperons in stellar objects such as neutron stars, our results should have phenomenological implications related to the so-called axion window. [ABSTRACT FROM AUTHOR]

Published

2021

19. Dark matter freeze-in from semi-production.

Author

Hryczuk, Andrzej and Laletin, Maxim

Abstract

We study a novel dark matter production mechanism based on the freeze-in through semi-production, i.e. the inverse semi-annihilation processes. A peculiar feature of this scenario is that the production rate is suppressed by a small initial abundance of dark matter and consequently creating the observed abundance requires much larger coupling values than for the usual freeze-in. We provide a concrete example model exhibiting such production mechanism and study it in detail, extending the standard formalism to include the evolution of dark matter temperature alongside its number density and discuss the importance of this improved treatment. Finally, we confront the relic density constraint with the limits and prospects for the dark matter indirect detection searches. We show that, even if it was never in full thermal equilibrium in the early Universe, dark matter could, nevertheless, have strong enough present-day annihilation cross section to lead to observable signals. [ABSTRACT FROM AUTHOR]

Published

2021

20. Displaced new physics at colliders and the early universe before its first second.

Author

Calibbi, Lorenzo, D'Eramo, Francesco, Junius, Sam, Lopez-Honorez, Laura, and Mariotti, Alberto

Subjects

PHYSICAL cosmology, PHYSICS, DARK matter, UNIVERSE, PARTICLE decays, HADRON colliders, INFLATIONARY universe

Abstract

Displaced vertices at colliders, arising from the production and decay of long-lived particles, probe dark matter candidates produced via freeze-in. If one assumes a standard cosmological history, these decays happen inside the detector only if the dark matter is very light because of the relic density constraint. Here, we argue how displaced events could very well point to freeze-in within a non-standard early universe history. Focusing on the cosmology of inflationary reheating, we explore the interplay between the reheating temperature and collider signatures for minimal freeze-in scenarios. Observing displaced events at the LHC would allow to set an upper bound on the reheating temperature and, in general, to gather indirect information on the early history of the universe. [ABSTRACT FROM AUTHOR]

Published

2021

21. Phase transition gravitational waves from pseudo-Nambu-Goldstone dark matter and two Higgs doublets.

Author

Zhang, Zhao, Cai, Chengfeng, Jiang, Xue-Min, Tang, Yi-Lei, Yu, Zhao-Huan, and Zhang, Hong-Hao

Subjects

DARK matter, FIRST-order phase transitions, PHASE transitions, SCALAR field theory, GRAVITATIONAL waves, GRAVITATIONAL potential, ELECTROWEAK interactions

Abstract

We investigate the potential stochastic gravitational waves from first-order electroweak phase transitions in a model with pseudo-Nambu-Goldstone dark matter and two Higgs doublets. The dark matter candidate can naturally evade direct detection bounds, and can achieve the observed relic abundance via the thermal mechanism. Three scalar fields in the model obtain vacuum expectation values, related to phase transitions at the early Universe. We search for the parameter points that can cause first-order phase transitions, taking into account the existed experimental constraints. The resulting gravitational wave spectra are further evaluated. Some parameter points are found to induce strong gravitational wave signals, which have the opportunity to be detected in future space-based interferometer experiments LISA, Taiji, and TianQin. [ABSTRACT FROM AUTHOR]

Published

2021

22. Dark matter in the type Ib seesaw model.

Author

Chianese, M., Fu, B., and King, S. F.

Subjects

DARK matter, DISCRETE symmetries, NEUTRINOS, NEUTRINO mass, STANDARD model (Nuclear physics), SCALAR field theory

Abstract

We consider a minimal type Ib seesaw model where the effective neutrino mass operator involves two different Higgs doublets, and the two right-handed neutrinos form a heavy Dirac mass. We propose a minimal dark matter extension of this model, in which the Dirac heavy neutrino is coupled to a dark Dirac fermion and a dark complex scalar field, both charged under a discrete Z2 symmetry, where the lighter of the two is a dark matter candidate. Focussing on the fermionic dark matter case, we explore the parameter space of the seesaw Yukawa couplings, the neutrino portal couplings and dark scalar to dark fermion mass ratio, where correct dark matter relic abundance can be produced by the freeze-in mechanism. By considering the mixing between the standard model neutrinos and the heavy neutrino, we build a connection between the dark matter production and current laboratory experiments ranging from collider to lepton flavour violating experiments. For a GeV mass heavy neutrino, the parameters related to dark matter production are constrained by the experimental results directly and can be further tested by future experiments such as SHiP. [ABSTRACT FROM AUTHOR]

Published

2021

23. Gravitational production of a conformal dark sector.

Author

Redi, Michele, Tesi, Andrea, and Tillim, Hannah

Subjects

DARK matter, GRAVITONS, STANDARD model (Nuclear physics), SPECIAL effects in lighting, PHASE transitions, DILATON

Abstract

Dark sectors with purely gravitational couplings to the Standard Model are unavoidably populated from the SM plasma by graviton exchange, and naturally provide dark matter candidates. We examine the production in the relativistic regime where the dark sector is approximately scale invariant, providing general analytical formulas that depend solely on the central charge of the dark sector. We then assess the relevance of interactions that can lead to a variety of phenomena including thermalisation, non-perturbative mass gaps, out-of-equilibrium phase transitions and cannibalism in the dark sector. As an illustrative example we consider the dark glueball scenario in this light and show it to be a viable dark matter candidate due to the suppression of gravitational production. We go on to extend these results to strongly coupled CFTs and their holographic duals at large-N with the dark dilaton as the dark matter candidate. [ABSTRACT FROM AUTHOR]

Published

2021

24. Light dark matter from inflaton decay.

Author

Moroi, Takeo and Yin, Wen

Subjects

DARK matter, STIMULATED emission, THERMAL plasmas, NEUTRINO mass, PLASMA temperature, AXIONS, SUPERGRAVITY, INFLATIONARY universe

Abstract

We propose a simple mechanism of light dark matter (DM) production from the decay of the oscillating inflaton condensation. If the reheating temperature after inflation is higher than the inflaton mass, which is of the same order of the momentum of the DM at the time of the production, the DM momentum can be suppressed compared to the temperature of the thermal plasma if the interaction of the DM is weak enough. Consequently, the DM can be cold enough to avoid the observational constraints on the warm DM, like the Lyman-α bound even if the DM mass is small. We study the bosonic and fermionic DM production from the inflaton decay, taking into account the effect of the stimulated emission and Pauli blocking, respectively. In both cases, the DM can be cold and abundant enough to be a viable candidate of the DM. We also apply our mechanism to the production of isocurvature-problem-free axion DM and Dirac sea DM of right-handed neutrino consistent the seesaw relation for the active neutrino masses. [ABSTRACT FROM AUTHOR]

Published

2021

25. Gravitational vector Dark Matter.

Author

Gross, Christian, Karamitsos, Sotirios, Landini, Giacomo, and Strumia, Alessandro

Subjects

DARK matter, BOUND states, PARTICLE interactions, GAUGE symmetries, NONABELIAN groups, PHYSICAL cosmology

Abstract

A new dark sector consisting of a pure non-abelian gauge theory has no renormalizable interaction with SM particles, and can thereby realise gravitational Dark Matter (DM). Gauge interactions confine at a scale ΛDM giving bound states with typical lifetimes τ ∼ M P 1 4 / Λ DM 5 that can be DM candidates if ΛDM is below 100 TeV. Furthermore, accidental symmetries of group-theoretical nature produce special gravitationally stable bound states. In the presence of generic Planck-suppressed operators such states become long-lived: SU(N) gauge theories contain bound states with τ ∼ M P 1 8 / Λ DM 9 ; even longer lifetimes τ = (MPl/ΛDM)2N−4/ΛDM arise from SO(N) theories with N ≥ 8, and possibly from F4 or E8. We compute their relic abundance generated by gravitational freeze-in and by inflationary fluctuations, finding that they can be viable DM candidates for ΛDM ≳ 1010 GeV. [ABSTRACT FROM AUTHOR]

Published

2021

26. Light(ly)-coupled dark matter in the keV range: freeze-in and constraints.

Author

Chang, Jae Hyeok, Essig, Rouven, and Reinert, Annika

Subjects

DARK matter, MAGNETIC dipole moments, ELECTRIC dipole moments, ANNIHILATION reactions, PLASMONS (Physics), COUPLING constants, PLASMA frequencies

Abstract

Dark matter produced from thermal freeze-out is typically restricted to have masses above roughly 1 MeV. However, if the couplings are small, the freeze-in mechanism allows for production of dark matter down to keV masses. We consider dark matter coupled to a dark photon that mixes with the photon and dark matter coupled to photons through an electric or magnetic dipole moment. We discuss contributions to the freeze-in production of such dark matter particles from standard model fermion-antifermion annihilation and plasmon decay. We also derive constraints on such dark matter from the cooling of red giant stars and horizontal branch stars, carefully evaluating the thermal processes as well as the bremsstrahlung process that dominates for masses above the plasma frequency. We find that the parameters needed to obtain the observed relic abundance from freeze-in are excluded below a few tens of keV, depending on the value of the dark gauge coupling constant for the dark photon portal model, and below a few keV, depending on the reheating temperature for dark matter with an electric or magnetic dipole moment. While laboratory probes are unlikely to probe these freeze-in scenarios in general, we show that for dark matter with an electric or magnetic dipole moment and for dark matter masses above the reheating temperature, the couplings needed for freeze-in to produce the observed relic abundance can be probed partially by upcoming direct-detection experiments. [ABSTRACT FROM AUTHOR]

Published

2021

27. Nucleation is more than critical: A case study of the electroweak phase transition in the NMSSM.

Author

Baum, Sebastian, Carena, Marcela, Shah, Nausheen R., Wagner, Carlos E. M., and Wang, Yikun

Subjects

PHASE transitions, NUCLEATION, CRITICAL temperature, STANDARD model (Nuclear physics), ELECTROWEAK interactions, BARYONS, HUMAN behavior models, NEUTRINO mass

Abstract

Electroweak baryogenesis is an attractive mechanism to generate the baryon asymmetry of the Universe via a strong first order electroweak phase transition. We compare the phase transition patterns suggested by the vacuum structure at the critical temperatures, at which local minima are degenerate, with those obtained from computing the probability for nucleation via tunneling through the barrier separating local minima. Heuristically, nucleation becomes difficult if the barrier between the local minima is too high, or if the distance (in field space) between the minima is too large. As an example of a model exhibiting such behavior, we study the Next-to-Minimal Supersymmetric Standard Model, whose scalar sector contains two SU(2) doublets and one gauge singlet. We find that the calculation of the nucleation probabilities prefers different regions of parameter space for a strong first order electroweak phase transition than the calculation based solely on the critical temperatures. Our results demonstrate that analyzing only the vacuum structure via the critical temperatures can provide a misleading picture of the phase transition patterns, and, in turn, of the parameter space suitable for electroweak baryogenesis. [ABSTRACT FROM AUTHOR]

Published

2021

28. Search for U1Lμ−Lτ charged dark matter with neutrino telescope.

Author

Asai, Kento, Okawa, Shohei, and Tsumura, Koji

Subjects

DARK matter, GAUGE bosons, NEUTRINO detectors, MASS spectrometry, RESONANCE effect, MUONS, NEUTRINOS

Abstract

We study a simple Dirac fermion dark matter model in U 1 L μ − L τ theory. The new light gauge boson X plays important roles in both dark matter physics and the explanation for the muon g− 2 anomaly. The observed dark matter relic density is realized by a large U 1 L μ − L τ charge without introducing a resonance effect of the X boson. As a by-product of the model, characteristic neutrino signatures from sub-GeV dark matter ψ are predicted depending on the mass spectrum. We formulate the analysis of ψ ψ ¯ → ν ν ¯ , and of ψ ψ ¯ → XX followed by X → ν ν ¯ in a model independent way. The energy spectrum of neutrinos in the former process is monochromatic while in the latter process is bowl-shape. We also evaluate sensitivity at Super-Kamiokande and future Hyper-Kamiokande detectors. The analysis is finally applied to the U 1 L μ − L τ dark matter model. [ABSTRACT FROM AUTHOR]

Published

2021

29. Lepto-axiogenesis.

Author

Co, Raymond T., Fernandez, Nicolas, Ghalsasi, Akshay, Hall, Lawrence J., and Harigaya, Keisuke

Subjects

AXIONS, YUKAWA interactions, HIGGS bosons, SUPERSYMMETRY, DECAY constants, NEUTRINO mass, RADIATION

Abstract

We propose a baryogenenesis mechanism that uses a rotating condensate of a Peccei-Quinn (PQ) symmetry breaking field and the dimension-five operator that gives Majorana neutrino masses. The rotation induces charge asymmetries for the Higgs boson and for lepton chirality through sphaleron processes and Yukawa interactions. The dimension-five interaction transfers these asymmetries to the lepton asymmetry, which in turn is transferred into the baryon asymmetry through the electroweak sphaleron process. QCD axion dark matter can be simultaneously produced by dynamics of the same PQ field via kinetic misalignment or parametric resonance, favoring an axion decay constant fa ≲ 1010 GeV, or by conventional misalignment and contributions from strings and domain walls with fa ∼ 1011 GeV. The size of the baryon asymmetry is tied to the mass of the PQ field. In simple supersymmetric theories, it is independent of UV parameters and predicts the supersymmtry breaking mass scale to be O (10 − 104) TeV, depending on the masses of the neutrinos and whether the condensate is thermalized during a radiation or matter dominated era. The high supersymmetry breaking mass scale may be free from cosmological and flavor/CP problems. We also construct a theory where TeV scale supersymmetry is possible. Parametric resonance may give warm axions, and the radial component of the PQ field may give signals in rare kaon decays from mixing with the Higgs and in dark radiation. [ABSTRACT FROM AUTHOR]

Published

2021

30. Gravitational wave signals of dark matter freeze-out.

Author

Marfatia, Danny and Tseng, Po-Yan

Abstract

We study the stochastic background of gravitational waves which accompany the sudden freeze-out of dark matter triggered by a cosmological first order phase transition that endows dark matter with mass. We consider models that produce the measured dark matter relic abundance via (1) bubble filtering, and (2) inflation and reheating, and show that gravitational waves from these mechanisms are detectable at future interferometers. [ABSTRACT FROM AUTHOR]

Published

2021

31. Light mass window of lepton portal dark matter.

Author

Okawa, Shohei and Omura, Yuji

Abstract

We explore a novel possibility that dark matter has a light mass below 1 GeV in a lepton portal dark matter model. There are Yukawa couplings involving dark matter, left-handed leptons and an extra scalar doublet in the model. In the light mass region, dark matter is thermally produced via its annihilation into neutrinos. In order to obtain the correct relic abundance and avoid collider bounds, a neutral scalar is required to be light while charged scalars need to be heavier than the electroweak scale. Such a mass spectrum is realized by adjusting quartic couplings in the scalar potential or introducing an extra singlet scalar. It turns out that the mass region of 10 MeV–10 GeV is almost free from experimental and observational constraints. We also point out that searches for extra neutrino flux from galactic dark matter annihilations with neutrino telescopes are the best way to test our model. [ABSTRACT FROM AUTHOR]

Published

2021

32. Ripples in spacetime from broken supersymmetry.

Author

Craig, Nathaniel, Levi, Noam, Mariotti, Alberto, and Redigolo, Diego

Abstract

We initiate the study of gravitational wave (GW) signals from first-order phase transitions in supersymmetry-breaking hidden sectors. Such phase transitions often occur along a pseudo-flat direction universally related to supersymmetry (SUSY) breaking in hidden sectors that spontaneously break R-symmetry. The potential along this pseudo-flat direction imbues the phase transition with a number of novel properties, including a nucleation temperature well below the scale of heavy states (such that the temperature dependence is captured by the low-temperature expansion) and significant friction induced by the same heavy states as they pass through bubble walls. In low-energy SUSY-breaking hidden sectors, the frequency of the GW signal arising from such a phase transition is guaranteed to lie within the reach of future interferometers given existing cosmological constraints on the gravitino abundance. Once a mediation scheme is specified, the frequency of the GW peak correlates with the superpartner spectrum. Current bounds on supersymmetry are compatible with GW signals at future interferometers, while the observation of a GW signal from a SUSY-breaking hidden sector would imply superpartners within reach of future colliders. [ABSTRACT FROM AUTHOR]

Published

2021

33. Exploring new physics with O(keV) electron recoils in direct detection experiments.

Author

Bloch, Itay M., Caputo, Andrea, Essig, Rouven, Redigolo, Diego, Sholapurkar, Mukul, and Volansky, Tomer

Abstract

Motivated by the recent XENON1T results, we explore various new physics models that can be discovered through searches for electron recoils in O (keV)-threshold direct-detection experiments. First, we consider the absorption of axion-like particles, dark photons, and scalars, either as dark matter relics or being produced directly in the Sun. In the latter case, we find that keV mass bosons produced in the Sun provide an adequate fit to the data but are excluded by stellar cooling constraints. We address this tension by introducing a novel Chameleon-like axion model, which can explain the excess while evading the stellar bounds. We find that absorption of bosonic dark matter provides a viable explanation for the excess only if the dark matter is a dark photon or an axion. In the latter case, photophobic axion couplings are necessary to avoid X-ray constraints. Second, we analyze models of dark matter-electron scattering to determine which models might explain the excess. Standard scattering of dark matter with electrons is generically in conflict with data from lower-threshold experiments. Momentum-dependent interactions with a heavy mediator can fit the data with dark matter mass heavier than a GeV but are generically in tension with collider constraints. Next, we consider dark matter consisting of two (or more) states that have a small mass splitting. The exothermic (down)scattering of the heavier state to the lighter state can fit the data for keV mass splittings. Finally, we consider a subcomponent of dark matter that is accelerated by scattering off cosmic rays, finding that dark matter interacting though an O (100 keV)-mass mediator can fit the data. The cross sections required in this scenario are, however, typically challenged by complementary probes of the light mediator. Throughout our study, we implement an unbinned Monte Carlo analysis and use an improved energy reconstruction of the XENON1T events. [ABSTRACT FROM AUTHOR]

Published

2021

34. What if ALP dark matter for the XENON1T excess is the inflaton.

Author

Takahashi, Fuminobu, Yamada, Masaki, and Yin, Wen

Abstract

The recent XENON1T excess in the electron recoil data can be explained by anomaly-free axion-like particle (ALP) dark matter with mass mϕ = 2.3 ± 0.2 keV and the decay constant f ϕ / q e ≃ 2 × 10 10 Ω ϕ / Ω DM GeV. Intriguingly, the suggested mass and decay constant are consistent with the relation, f ϕ ∼ 10 3 m ϕ M p , predicted in a scenario where the ALP plays the role of the inflaton. This raises a possibility that the ALP dark matter responsible for the XENON1T excess also drove inflation in the very early universe. We study implications of the XENON1T excess for the ALP inflation and thermal history of the universe after inflation. We find that the successful reheating requires the ALP couplings to heavy fermions in the standard model, which results in an instantaneous reheating and subsequent thermalization of the ALPs. Then, an entropy dilution of O (10) is necessary to explain the XENON1T excess, which can be achieved by decays of the right-handed neutrinos. [ABSTRACT FROM AUTHOR]

Published

2021

35. Boosting GWs in supersolid inflation.

Author

Celoria, Marco, Comelli, Denis, Pilo, Luigi, and Rollo, Rocco

Abstract

Inflation driven by a generic self-gravitating medium is an interesting alternative to study the impact of spontaneous spacetime symmetry breaking during a quasi de-Sitter phase, in particular the 4-dimensional diffeomorphism invariance of GR is spontaneously broken down to I SO(3). The effective description is based on four scalar fields that describe the excitations of a supersolid. There are two phonon-like propagating scalar degrees of freedom that mix non-trivially both at early and late times and, after exiting the horizon, give rise to non-trivial correlations among the different scalar power spectra. The non-linear structure of the theory allows a secondary gravitational waves production during inflation, efficient enough to saturate the present experimental bound and with a blue-tilted spectral index. [ABSTRACT FROM AUTHOR]

Published

2021

36. Dark photon dark matter in the minimal B − L model.

Author

Choi, Gong jun, Yanagida, Tsutomu T., and Yokozaki, Norimi

Abstract

The extension of the Standard model (SM) with three heavy right handed neutrinos, a complex scalar and the gauged U(1)B−L symmetry (the minimal B − L model) is considered the most compelling minimal one: the presence and the out-of-equilibrium decay of the heavy right handed neutrinos can account for the small masses of the active neutrinos and the baryon asymmetry of the universe. A natural accompanying question concerns whether the minimal B − L model can naturally accommodate an interesting dark matter (DM) candidate. We study the possibility where the current DM population is explained by the gauge boson of U(1)B−L symmetry. We discuss how the minimal set-up originally aimed at the seesaw mechanism and the leptogenesis is connected to conditions making the gauge boson promoted to a DM candidate. [ABSTRACT FROM AUTHOR]

Published

2021

37. Exothermic dark matter for XENON1T excess.

Author

Lee, Hyun Min

Subjects

DARK matter, ATOMIC excitation, EXCESS electrons, PHASES of matter, GAUGE symmetries

Abstract

Motivated by the recent excess in the electron recoil from XENON1T experiment, we consider the possibility of exothermic dark matter, which is composed of two states with mass splitting. The heavier state down-scatters off the electron into the lighter state, making an appropriate recoil energy required for the Xenon excess even for the standard Maxwellian velocity distribution of dark matter. Accordingly, we determine the mass difference between two component states of dark matter to the peak electron recoil energy at about 2.5 keV up to the detector resolution, accounting for the recoil events over ER = 2 − 3 keV, which are most significant. We include the effects of the phase-space enhancement and the atomic excitation factor to calculate the required scattering cross section for the Xenon excess. We discuss the implications of dark matter interactions in the effective theory for exothermic dark matter and a massive Z′ mediator and provide microscopic models realizing the required dark matter and electron couplings to Z′. [ABSTRACT FROM AUTHOR]

Published

2021

38. Flavour effects in gravitational leptogenesis.

Author

Samanta, Rome and Datta, Satyabrata

Abstract

Within the Type-I seesaw mechanism, quantum effects of the right-handed (RH) neutrinos in the gravitational background lead to an asymmetric propagation of lepton and anti-leptons which induces a Ricci scalar and neutrino Dirac-Yukawa coupling dependent chemical potential and therefore a lepton asymmetry in equilibrium. At high temperature, lepton number violating scattering processes try to maintain a dynamically generated lepton asymmetry in equilibrium. However, when the temperature drops down, the interactions become weaker, and the asymmetry freezes out. The frozen out asymmetry can act as a pre-existing asymmetry prior to the standard Fukugita-Yanagida leptogenesis phase (Ti ∼ Mi, where Mi is the mass of ith RH neutrino). It is then natural to consider the viability of gravitational leptogenesis for a given RH mass spectrum which is not consistent with successful leptogenesis from decays. Primary threat to this gravity-induced lepton asymmetry to be able to successfully reproduce the observed baryon-to-photon ratio is the lepton number violating washout processes at Ti ∼ Mi. In a minimal seesaw set up with two RH neutrinos, these washout processes are strong enough to erase a pre-existing asymmetry of significant magnitude. We show that when effects of flavour on the washout processes are taken into account, the mechanism opens up the possibility of successful leptogenesis (gravitational) for a mass spectrum M2 » 109GeV » M1 with M1 ≳ 6.3 × 106 GeV. We then briefly discuss how, in general, the mechanism leaves its imprints on the low energy CP phases and absolute light neutrino mass scale. [ABSTRACT FROM AUTHOR]

Published

2020

39. Axion quality from the (anti)symmetric of SU(N).

Author

Ardu, Marco, Di Luzio, Luca, Landini, Giacomo, Strumia, Alessandro, Teresi, Daniele, and Wang, Jin-Wei

Subjects

AXIONS, SYMMETRY breaking, THERMAL equilibrium, DARK matter, FERMIONS

Abstract

We propose two models where a U(1) Peccei-Quinn global symmetry arises accidentally and is respected up to high-dimensional operators, so that the axion solution to the strong CP problem is successful even in the presence of Planck-suppressed operators. One model is SU(N ) gauge interactions with fermions in the fundamental and a scalar in the symmetric. The axion arises from spontaneous symmetry breaking to SO(N ), that confines at a lower energy scale. Axion quality in the model needs N ≳ 10. SO bound states and possibly monopoles provide extra Dark Matter candidates beyond the axion. In the second model the scalar is in the anti-symmetric: SU(N ) broken to Sp(N ) needs even N ≳ 20. The cosmological DM abundance, consisting of axions and/or super-heavy relics, can be reproduced if the PQ symmetry is broken before inflation (Boltzmann-suppressed production of super-heavy relics) or after (super-heavy relics in thermal equilibrium get partially diluted by dark glue-ball decays). [ABSTRACT FROM AUTHOR]

Published

2020

40. Dark matter bound-state formation at higher order: a non-equilibrium quantum field theory approach.

Author

Binder, Tobias, Blobel, Burkhard, Harz, Julia, and Mukaida, Kyohei

Abstract

The formation of meta-stable dark matter bound states in coannihilating scenarios could efficiently occur through the scattering with a variety of Standard Model bath particles, where light bosons during the electroweak cross over or even massless photons and gluons are exchanged in the t-channel. The amplitudes for those higher-order processes, however, are divergent in the collinear direction of the in- and out-going bath particles if the mediator is massless. To address the issue of collinear divergences, we derive the bound-state formation collision term in the framework of non-equilibrium quantum field theory. The main result is an expression for a more general cross section, which allows to compute higher-order bound-state formation processes inside the primordial plasma background in a comprehensive manner. Based on this result, we show that next-to-leading order contributions, including the bath-particle scattering, are i) collinear finite and ii) generically dominate over the on-shell emission for temperatures larger than the absolute value of the binding energy. Based on a simplified model, we demonstrate that the impact of these new effects on the thermal relic abundance is significant enough to make it worthwhile to study more realistic coannihilation scenarios. [ABSTRACT FROM AUTHOR]

Published

2020

41. Connecting between inflation and dark matter in models with gauged Z3 symmetry.

Author

Choi, Soo-Min, Kim, Jinsu, Lee, Hyun Min, and Zhu, Bin

Subjects

DARK matter, INFLATIONARY universe, DISCRETE symmetries, SYMMETRY breaking, SYMMETRY, FORECASTING, CALCIUM channels, PARITY (Physics)

Abstract

We investigate the possibility of unifying the inflation and dark matter physics in the minimal model for a complex scalar dark matter with gauged Z3 symmetry. The dark local U(1) symmetry is broken spontaneously into the Z3 symmetry by the dark Higgs mechanism. As compared to dark matter models with Z2 parity, the dark matter cubic self-interaction restricts the inflation with non-minimal couplings to take place beyond the pure dark matter direction and plays an important role in the loop corrections for the inflationary predictions as well as determining the correct dark matter relic density. Considering either of 2 → 2, 3 → 2 or forbidden channels to be a dominant production mechanism for dark matter, we show the viable parameter space of the model that is consistent with the theoretical and phenomenological constraints combined from inflation and dark matter. [ABSTRACT FROM AUTHOR]

Published

2020

42. Direct detection and complementary constraints for sub-GeV dark matter.

Author

Bondarenko, Kyrylo, Boyarsky, Alexey, Bringmann, Torsten, Hufnagel, Marco, Schmidt-Hoberg, Kai, and Sokolenko, Anastasia

Abstract

Traditional direct searches for dark matter, looking for nuclear recoils in deep underground detectors, are challenged by an almost complete loss of sensitivity for light dark matter particles. Consequently, there is a significant effort in the community to devise new methods and experiments to overcome these difficulties, constantly pushing the limits of the lowest dark matter mass that can be probed this way. From a model-building perspective, the scattering of sub-GeV dark matter on nucleons essentially must proceed via new light mediator particles, given that collider searches place extremely stringent bounds on contact-type interactions. Here we present an updated compilation of relevant limits for the case of a scalar mediator, including a new estimate of the near-future sensitivity of the NA62 experiment as well as a detailed evaluation of the model-specific limits from Big Bang nucleosynthesis. We also derive updated and more general limits on DM particles upscattered by cosmic rays, applicable to arbitrary energy- and momentum dependences of the scattering cross section. Finally we stress that dark matter self-interactions, when evaluated beyond the common s-wave approximation, place stringent limits independently of the dark matter production mechanism. These are, for the relevant parameter space, generically comparable to those that apply in the commonly studied freeze-out case. We conclude that the combination of existing (or expected) constraints from accelerators and astrophysics, combined with cosmological requirements, puts robust limits on the maximally possible nuclear scattering rate. In most regions of parameter space these are at least competitive with the best projected limits from currently planned direct detection experiments. [ABSTRACT FROM AUTHOR]

Published

2020

43. Light Dark Matter from Entropy Dilution.

Author

Evans, Jared A., Ghalsasi, Akshay, Gori, Stefania, Tammaro, Michele, and Zupan, Jure

Abstract

We show that a thermal relic which decouples from the standard model (SM) plasma while relativistic can be a viable dark matter (DM) candidate, if the decoupling is followed by a period of entropy dilution that heats up the SM, but not the dark sector. Such diluted hot relics can be as light as few keV, while accounting for the entirety of the DM, and not conflicting with cosmological and astrophysical measurements. The requisite dilution can be achieved via decays of a heavy state that dominates the energy budget of the universe in the early matter dominated era. The heavy state decays into the SM particles, heats up the SM plasma, and dilutes the hidden sector. The interaction required to equilibrate the two sectors in the early universe places a bound on the maximum possible dilution as a function of the decoupling temperature. As an example of diluted hot relic DM we consider a light Dirac fermion with a heavy dark photon mediator. We present constraints on the model from terrestrial experiments (current and future), astrophysics, and cosmology. [ABSTRACT FROM AUTHOR]

Published

2020

44. Leak-in dark matter.

Author

Evans, Jared A., Gaidau, Cristian, and Shelton, Jessie

Abstract

We introduce leak-in dark matter, a novel out-of-equilibrium origin for the dark matter (DM) in the universe. We provide a comprehensive and unified discussion of a minimal, internally-thermalized, hidden sector populated from an out-of-equilibrium, feeble connection to the hotter standard model (SM) sector. We emphasize that when this out-of-equilibrium interaction is renormalizable, the colder sector undergoes an extended phase of non-adiabatic evolution largely independent of initial conditions, which we dub “leak-in.” We discuss the leak-in phase in generality, and establish the general properties of dark matter that freezes out from a radiation bath undergoing such a leak-in phase. As a concrete example, we consider a model where the SM has an out-of-equilibrium B − L vector portal interaction with a minimal hidden sector. We discuss the interplay between leak-in and freezein processes in this theory in detail and demonstrate regions where leak-in yields the full relic abundance. We study observational prospects for B − L vector portal leak-in DM, and find that despite the requisite small coupling to the SM, a variety of experiments can serve as sensitive probes of leak-in dark matter. Additionally, regions allowed by all current constraints yield DM with self-interactions large enough to address small-scale structure anomalies. [ABSTRACT FROM AUTHOR]

Published

2020

45. Heavy spinning particles from signs of primordial non-gaussianities: beyond the positivity bounds.

Author

Kim, Suro, Noumi, Toshifumi, Takeuchi, Keito, and Zhou, Siyi

Subjects

PARTICLE spin

Abstract

Within the so-called cosmological collider program, imprints of new particles on primordial non-Gaussianities have been studied intensively. In particular, their non- analytic features in the soft limit provide a smoking gun for new particles at the inflation scale. While this approach is very powerful to probe particles of the mass near the Hubble scale, the signal is exponentially suppressed for heavy particles. In this paper, to enlarge the scope of the cosmological collider, we explore a new approach to probing spins of heavy particles from signs of Wilson coefficients of the inflaton effective action and the corresponding primordial non-Gaussianities. As a first step, we focus on the regime where the de Sitter conformal symmetry is weakly broken. It is well known that the leading order effective operator (∂μ𝜙∂μ𝜙)2 is universally positive as a consequence of unitarity. In contrast, we find that the sign of the six derivative operator (∇μ∂ν𝜙)2(∂ρ𝜙)2 is positive for intermediate heavy scalars, whereas it is negative for intermediate heavy spinning states. Therefore, under the assumption of tree-level UV completion, the sign can be used to probe spins of heavy particles generating the effective interaction. We also study phenomenology of primordial non-Gaussianities thereof. [ABSTRACT FROM AUTHOR]

Published

2019

46. Unitary inflaton as decaying dark matter.

Author

Choi, Soo-Min, Kang, Yoo-Jin, Lee, Hyun Min, and Yamashita, Kimiko

Published

2019

47. The supercooled universe.

Author

Baratella, Pietro, Pomarol, Alex, and Rompineve, Fabrizio

Published

2019

48. Leptophilic dark matter from gauged lepton number: phenomenology and gravitational wave signatures.

Author

Madge, Eric and Schwaller, Pedro

Published

2019

49. Unitarity and CP violation in leptogenesis at NLO: general considerations and top Yukawa contributions.

Author

Racker, J.

Published

2019

50. Low-scale leptogenesis with three heavy neutrinos.

Author

Abada, Asmaa, Arcadi, Giorgio, Domcke, Valerie, Drewes, Marco, Klaric, Juraj, and Lucente, Michele

Published

2019