Composite dark matter from strongly-interacting chiral dynamics

Contino, Roberto; Podo, Alessandro; Revello, Filippo

doi:10.1007/jhep02(2021)091

Cited by 18 publications

(26 citation statements)

References 79 publications

(146 reference statements)

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“…Dark Matter (DM) might be an accidentally stable dark baryon made of dark quarks q colored under a new dark gauge group [1][2][3][4][5][6][7][8][9][10][11][12][13]. In models with an appropriate number of light dark quark flavours the dark confinement phase transition is first-order and has interesting cosmological implications [14,15]: relic dark quarks tend to remain in the false vacuum (because they are lighter than dark baryons in the true vacuum), so expanding bubbles of the true vacuum compress them down to small pockets.…”

Section: Introductionmentioning

confidence: 99%

Dark Matter as dark dwarfs and other macroscopic objects: multiverse relics?

Groß

Landini

Струмиа

et al. 2021

J. High Energ. Phys.

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First order phase transitions can leave relic pockets of false vacua and their particles, that manifest as macroscopic Dark Matter. We compute one predictive model: a gauge theory with a dark quark relic heavier than the confinement scale. During the first order phase transition to confinement, dark quarks remain in the false vacuum and get compressed, forming Fermi balls that can undergo gravitational collapse to stable dark dwarfs (bound states analogous to white dwarfs) near the Chandrasekhar limit, or primordial black holes.

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Section: Introductionmentioning

confidence: 99%

Dark Matter as dark dwarfs and other macroscopic objects: multiverse relics?

Groß

Landini

Струмиа

et al. 2021

J. High Energ. Phys.

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“…2. We have studied the signals of the model at gravitational waves interferometers, colliders, direct and indirect detection experiments, for the cases where DM is a heavy scalar, 17 Other ways to evade this bound are, for example, DM dilution after a matter era [128,[218][219][220][221][222][223][224][225][226][227], or having a dark sector being much cooler than SM [237,238], DM becoming heavy only after freezing-out [239], DM annihilating with one spectator field [240] or with many of them [241], DM forming an extended object which undergoes a second annihilation stage [228][229][230]. Mechanisms involving phase transitions include the possibility of a short inflationary stage associated with perturbative DM mass generation [147], DM filtered [231,232] or squeezed-out [233,234] by non-relativistic bubble wall motion, DM produced by elastic bubble-bubble collisions [235] or perturbative plasma interactions with relativistic walls [236].…”

Section: Discussionmentioning

confidence: 99%

Supercool Composite Dark Matter Beyond 100 TeV

Baldes,

Gouttenoire,

Sala

et al. 2021

Preprint

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Dark matter could be a composite state of a confining sector with an approximate scale symmetry. We consider the case where the associated pseudo-Goldstone boson, the dilaton, mediates its interactions with the Standard Model. When the confining phase transition in the early universe is supercooled, its dynamics allows for dark matter masses up to 10 6 TeV. We derive the precise parameter space compatible with all experimental constraints, finding that this scenario can be tested partly by telescopes and entirely by gravitational waves.

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“…Moreover, such a semi-inclusive approach particularly balances the broadness of the signal space and the usage of kinematics to suppress the background, which will complement the traditional exclusive searches and possible more modelagnostic searches. This strategy can be followed in many different channels, such as W/Z/h-decay to multiple sterile neutrinos [52], continium dark sector [53][54][55], and generally hidden strong dynamics. It is also useful to extend the study of off-shell heavy standard model particle decays, as well as the search of BSM particle decays such as W , Z , top partners and heavy Higgs.…”

Section: Discussionmentioning

confidence: 99%

Probing Higgs exotic decay at the LHC with machine learning

Jung,

Liu,

Wang

et al. 2021

Preprint

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We study the tagging of Higgs exotic decay signals using different types of deep neural networks (DNNs), focusing on the W ± h associated production channel followed by Higgs decaying into n b-quarks with n = 4, 6 and 8. All the Higgs decay products are collected into a fat-jet, to which we apply further selection using the DNNs. Three kinds of DNNs are considered, namely convolutional neural network (CNN), recursive neural network (RecNN) and particle flow network (PFN). The PFN can achieve the best performance because its structure allows enfolding more information in addition to the four-momentums of the jet constituents, such as particle ID and tracks parameters. Using the PFN as an example, we verify that it can serve as an efficient tagger even though it is trained on a different event topology with different b-multiplicity from the actual signal. The projected sensitivity to the branching ratio of Higgs decaying into n b-quarks at the HL-LHC are 10%, 3% and 1%, for n = 4, 6 and 8, respectively.

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Composite dark matter from strongly-interacting chiral dynamics

Cited by 18 publications

References 79 publications

Dark Matter as dark dwarfs and other macroscopic objects: multiverse relics?

Dark Matter as dark dwarfs and other macroscopic objects: multiverse relics?

Supercool Composite Dark Matter Beyond 100 TeV

Probing Higgs exotic decay at the LHC with machine learning

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