Dark matter evidence, particle physics candidates and detection methods

Astroparticle physics deals with the investigation of cosmic radiation using similar detection methods as in particle physics, however, mostly with quite different detector arrangements. In this chapter the detection principles for the different radiation types with cosmic origin are presented, this includes charged particles, gamma radiation, neutrinos and possibly existing Dark Matter. In the case of neutrinos also experiments at accelerators and reactors are included. Examples, which are typical for the different areas, are given for detectors and their properties. For cosmic ray detection apparatuses are deployed above the atmosphere with balloons or satellites or on the ground using the atmosphere as calorimeter in which high-energy cosmic rays develop showers or in underground areas including in water and ice.

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DARK MATTER SEARCH

International Journal of Modern Physics A ◽

10.1142/s0217751x0201282x ◽

2002 ◽

Vol 17 (24) ◽

pp. 3421-3431 ◽

Cited By ~ 6

Author(s):

◽

H. V. KLAPDOR-KLEINGROTHAUS

Keyword(s):

Dark Matter ◽

Particle Physics ◽

Exciting Field ◽

Dark Matter Search ◽

The Status

Dark matter is at present one of the most exciting field of particle physics and cosmology. We review the status of undergound experiments looking for cold and hot dark matter.

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Xenon-1T excess as a possible signal of a sub-GeV hidden sector dark matter

Journal of High Energy Physics ◽

10.1007/jhep02(2021)229 ◽

2021 ◽

Vol 2021 (2) ◽

Author(s):

Amin Aboubrahim ◽

Michael Klasen ◽

Pran Nath

Keyword(s):

Dark Matter ◽

Particle Physics ◽

Small Mass ◽

Big Bang ◽

Mass Splitting ◽

Recoil Energy ◽

Dirac Fermions ◽

Dark Sector ◽

Dark Photon ◽

Physics Model

Abstract We present a particle physics model to explain the observed enhancement in the Xenon-1T data at an electron recoil energy of 2.5 keV. The model is based on a U(1) extension of the Standard Model where the dark sector consists of two essentially mass degenerate Dirac fermions in the sub-GeV region with a small mass splitting interacting with a dark photon. The dark photon is unstable and decays before the big bang nucleosynthesis, which leads to the dark matter constituted of two essentially mass degenerate Dirac fermions. The Xenon-1T excess is computed via the inelastic exothermic scattering of the heavier dark fermion from a bound electron in xenon to the lighter dark fermion producing the observed excess events in the recoil electron energy. The model can be tested with further data from Xenon-1T and in future experiments such as SuperCDMS.

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Dark matter, dark energy and gravity

International Journal of Modern Physics E ◽

10.1142/s0218301315500123 ◽

2015 ◽

Vol 24 (02) ◽

pp. 1550012 ◽

Cited By ~ 2

Author(s):

B. A. Robson

Keyword(s):

Dark Matter ◽

Dark Energy ◽

Particle Physics ◽

Composite Structures ◽

Gravitational Interaction ◽

Asymptotic Freedom ◽

Generation Model ◽

Newtonian Gravitation ◽

Color Confinement ◽

Vector Bosons

Within the framework of the Generation Model (GM) of particle physics, gravity is identified with the very weak, universal and attractive residual color interactions acting between the colorless particles of ordinary matter (electrons, neutrons and protons), which are composite structures. This gravitational interaction is mediated by massless vector bosons (hypergluons), which self-interact so that the interaction has two additional features not present in Newtonian gravitation: (i) asymptotic freedom and (ii) color confinement. These two additional properties of the gravitational interaction negate the need for the notions of both dark matter and dark energy.

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PROBING GRAVITATIONAL INTERACTIONS OF ELEMENTARY PARTICLES

International Journal of Modern Physics D ◽

10.1142/s0218271804006474 ◽

2004 ◽

Vol 13 (10) ◽

pp. 2355-2359 ◽

Cited By ~ 37

Author(s):

JONATHAN L. FENG ◽

ARVIND RAJARAMAN ◽

FUMIHIRO TAKAYAMA

Keyword(s):

Dark Matter ◽

Early Universe ◽

Particle Physics ◽

Gravitational Constant ◽

Planck Scale ◽

Elementary Particles ◽

Supersymmetric Particle ◽

Small Scales ◽

Physics Experiments ◽

Shed Light

The gravitational interactions of elementary particles are suppressed by the Planck scale M*~1018 GeV and are typically expected to be far too weak to be probed by experiments. We show that, contrary to conventional wisdom, such interactions may be studied by particle physics experiments in the next few years. As an example, we consider conventional supergravity with a stable gravitino as the lightest supersymmetric particle. The next-lightest supersymmetric particle (NLSP) decays to the gravitino through gravitational interactions after about a year. This lifetime can be measured by stopping NLSPs at colliders and observing their decays. Such studies will yield a measurement of Newton's gravitational constant on unprecedentedly small scales, shed light on dark matter, and provide a window on the early universe.

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Effective theories with dark matter applications

International Journal of Modern Physics D ◽

10.1142/s0218271821300044 ◽

2021 ◽

Author(s):

Subhaditya Bhattacharya ◽

José Wudka

Keyword(s):

Field Theory ◽

Dark Matter ◽

Effective Field Theory ◽

Particle Physics ◽

High Energy ◽

New Physics ◽

Effective Field ◽

The Subject ◽

Effective Theories ◽

Detailed Nature

Standard Model (SM) of particle physics has achieved enormous success in describing the interactions among the known fundamental constituents of nature, yet it fails to describe phenomena for which there is very strong experimental evidence, such as the existence of dark matter, and which point to the existence of new physics not included in that model; beyond its existence, experimental data, however, have not provided clear indications as to the nature of that new physics. The effective field theory (EFT) approach, the subject of this review, is designed for this type of situations; it provides a consistent and unbiased framework within which to study new physics effects whose existence is expected but whose detailed nature is known very imperfectly. We will provide a description of this approach together with a discussion of some of its basic theoretical aspects. We then consider applications to high-energy phenomenology and conclude with a discussion of the application of EFT techniques to the study of dark matter physics and its possible interactions with the SM. In several of the applications we also briefly discuss specific models that are ultraviolet complete and may realize the effects described by the EFT.

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The Search for Feebly Interacting Particles

Annual Review of Nuclear and Particle Science ◽

10.1146/annurev-nucl-102419-055056 ◽

2021 ◽

Vol 71 (1) ◽

pp. 279-313

Author(s):

Gaia Lanfranchi ◽

Maxim Pospelov ◽

Philip Schuster

Keyword(s):

Dark Matter ◽

Particle Physics ◽

Interaction Strength ◽

New Physics ◽

Fine Tuning ◽

Experimental Program ◽

Interacting Particles ◽

Fundamental Physics ◽

The Standard Model ◽

The Universe

At the dawn of a new decade, particle physics faces the challenge of explaining the mystery of dark matter, the origin of matter over antimatter in the Universe, the apparent fine-tuning of the electroweak scale, and many other aspects of fundamental physics. Perhaps the most striking frontier to emerge in the search for answers involves New Physics at mass scales comparable to that of familiar matter—below the GeV scale but with very feeble interaction strength. New theoretical ideas to address dark matter and other fundamental questions predict such feebly interacting particles (FIPs) at these scales, and existing data may even provide hints of this possibility. Emboldened by the lessons of the LHC, a vibrant experimental program to discover such physics is underway, guided by a systematic theoretical approach that is firmly grounded in the underlying principles of the Standard Model. We give an overview of these efforts, their motivations, and the decadal goals that animate the community involved in the search for FIPs, and we focus in particular on accelerator-based experiments.

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Dark Matter: A Primer

Advances in Astronomy ◽

10.1155/2011/968283 ◽

2011 ◽

Vol 2011 ◽

pp. 1-22 ◽

Cited By ~ 54

Author(s):

Katherine Garrett ◽

Gintaras Duda

Keyword(s):

Dark Matter ◽

Detection Methods ◽

Advanced Students ◽

Extensive List

Dark matter is one of the greatest unsolved mysteries in cosmology at the present time. About 80% of the Universe's gravitating matter is nonluminous, and its nature and distribution are for the most part unknown. In this paper, we will outline the history, astrophysical evidence, candidates, and detection methods of dark matter, with the goal to give the reader an accessible but rigorous introduction to the puzzle of dark matter. This paper targets advanced students and researchers new to the field of dark matter, and includes an extensive list of references for further study.

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Dark Matter Searches at Colliders

Annual Review of Nuclear and Particle Science ◽

10.1146/annurev-nucl-101917-021008 ◽

2018 ◽

Vol 68 (1) ◽

pp. 429-459 ◽

Cited By ~ 27

Author(s):

Antonio Boveia ◽

Caterina Doglioni

Keyword(s):

Dark Matter ◽

Large Hadron Collider ◽

Particle Physics ◽

Hadron Collider ◽

The Future ◽

Particle Dark Matter ◽

Near Future

Colliders, among the most successful tools of particle physics, have revealed much about matter. This review describes how colliders contribute to the search for particle dark matter, focusing on the highest-energy collider currently in operation, the Large Hadron Collider (LHC) at CERN. In the absence of hints about the character of interactions between dark matter and standard matter, this review emphasizes what could be observed in the near future, presents the main experimental challenges, and discusses how collider searches fit into the broader field of dark matter searches. Finally, it highlights a few areas to watch for the future LHC program.

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Hidden sector monopole dark matter with matter domination

Journal of High Energy Physics ◽

10.1007/jhep11(2020)133 ◽

2020 ◽

Vol 2020 (11) ◽

Author(s):

Michael L. Graesser ◽

Jacek K. Osiński

Keyword(s):

Dark Matter ◽

Cross Sections ◽

Particle Physics ◽

Magnetic Monopoles ◽

Number Density ◽

Pure Radiation ◽

Hidden Sector ◽

Equilibrium Dynamics ◽

Thermal Histories ◽

Relic Abundance

Abstract The thermal freeze-out mechanism for relic dark matter heavier than O(10 − 100 TeV) requires cross-sections that violate perturbative unitarity. Yet the existence of dark matter heavier than these scales is certainly plausible from a particle physics perspective, pointing to the need for a non-thermal cosmological history for such theories. Topological dark matter is a well-motivated scenario of this kind. Here the hidden-sector dark matter can be produced in abundance through the Kibble-Zurek mechanism describing the non-equilibrium dynamics of defects produced in a second order phase transition. We revisit the original topological dark matter scenario, focusing on hidden-sector magnetic monopoles, and consider more general cosmological histories. We find that a monopole mass of order (1–105) PeV is generic for the thermal histories considered here, if monopoles are to entirely reproduce the current abundance of dark matter. In particular, in a scenario involving an early era of matter domination, the monopole number density is always less than or equal to that in a pure radiation dominated equivalent provided a certain condition on critical exponents is satisfied. This results in a larger monopole mass needed to account for a fixed relic abundance in such cosmologies.

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