Light Dark Matter

From Handwiki
Short description: Dark matter weakly interacting massive particles candidates with masses less than 1 GeV
Part of a series on
Physical cosmology
Full-sky image derived from nine years' WMAP data
  • Big Bang · Universe
  • Age of the universe
  • Chronology of the universe
Early universe
  • Planck epoch
  • Grand unification epoch
  • Electroweak epoch
  • Quark epoch
  • Hadron epoch
  • Lepton epoch
  • Photon epoch
  • Big Bang nucleosynthesis
  • Inflation
  • Dark Ages
Backgrounds
  • Cosmic background radiation (CBR)
  • Gravitational wave background (GWB)
  • Cosmic microwave background (CMB) · Cosmic neutrino background (CNB)
  • Cosmic infrared background (INB)
Expansion · Future
  • Hubble's law · Redshift
  • Expansion of the universe
  • Accelerating expansion of the universe
  • Comoving and proper distances
  • FLRW metric · Friedmann equations
  • Inhomogeneous cosmology
  • Future of an expanding universe
  • Ultimate fate of the universe
  • Heat death of the universe
  • Big Rip
  • Big Crunch
  • Big Bounce
Components · Structure
Components
  • Lambda-CDM model
  • Baryonic matter
  • Energy
  • Radiation
  • Dark energy
    • Quintessence
    • Phantom energy
  • Dark matter
    • Cold dark matter
    • Warm dark matter
    • Hot dark matter
  • Dark radiation
Structure
  • Shape of the universe
  • Reionization · Structure formation
  • Galaxy formation
  • Large-scale structure
  • Large quasar group
  • Galaxy filament
  • Supercluster
  • Galaxy cluster
  • Galaxy group
  • Local Group
  • Galaxy
    • Dark matter halo
  • Star cluster
  • Solar system
  • Planetary system
  • Void
Experiments
  • BOOMERanG
  • Cosmic Background Explorer (COBE)
  • Dark Energy Survey
  • Euclid
  • Illustris project
  • Large Synoptic Survey Telescope
  • Planck space observatory
  • Sloan Digital Sky Survey (SDSS)
  • 2dF Galaxy Redshift Survey ("2dF")
  • UniverseMachine
  • Wilkinson Microwave Anisotropy
    Probe (WMAP)
  • Scientists
  • Aaronson
  • Alfvén
  • Alpher
  • Bharadwaj
  • Copernicus
  • de Sitter
  • Dicke
  • Eddington
  • Ehlers
  • Einstein
  • Ellis
  • Friedman
  • Galileo
  • Gamow
  • Guth
  • Hubble
  • Lemaître
  • Linde
  • Mather
  • Newton
  • Penzias
  • Rubin
  • Schmidt
  • Schwarzschild
  • Smoot
  • Starobinsky
  • Steinhardt
  • Suntzeff
  • Sunyaev
  • Tolman
  • Wilson
  • Zeldovich
    		•
    Subject history
    • Discovery of cosmic microwave
      background radiation
    • History of the Big Bang theory
    • Religious interpretations of
      the Big Bang theory
    • Timeline of cosmological theories
    • Category Category
    • v
    • t
    • e

    Light dark matter, in astronomy and cosmology, are dark matter weakly interacting massive particles (WIMPS) candidates with masses less than 1 GeV.[1] These particles are heavier than warm dark matter and hot dark matter, but are lighter than the traditional forms of cold dark matter, such as Massive Compact Halo Objects (MACHOs). The Lee-Weinberg bound [2] limits the mass of the favored dark matter candidate, WIMPs, that interact via the weak interaction to [math]\displaystyle{ \approx 2 }[/math] GeV. This bound arises as follows. The lower the mass of WIMPs is, the lower the annihilation cross section, which is of the order [math]\displaystyle{ \approx m^2/M^4 }[/math], where m is the WIMP mass and M the mass of the Z-boson. This means that low mass WIMPs, which would be abundantly produced in the early universe, freeze out (i.e. stop interacting) much earlier and thus at a higher temperature, than higher mass WIMPs. This leads to a higher relic WIMP density. If the mass is lower than [math]\displaystyle{ \sim 2 }[/math] GeV the WIMP relic density would overclose the universe.

    Some of the few loopholes allowing one to avoid the Lee-Weinberg bound without introducing new forces below the electroweak scale have been ruled out by accelerator experiments (i.e. CERN, Tevatron), and in decays of B mesons.[3]

    A viable way of building light dark matter models is thus by postulating new light bosons. This increases the annihilation cross section and reduces the coupling of dark matter particles to the Standard Model making them consistent with accelerator experiments.[4][5][6]

    Motivation

    In recent years, light dark matter has become popular due in part to the many benefits of the theory. Sub-GeV dark matter has been used to explain the positron excess in the galactic center observed by INTEGRAL, excess gamma rays from the galactic center [7] and extragalactic sources. It has also been suggested that light dark matter may explain a small discrepancy in the measured value of the fine structure constant in different experiments.[8]

    See also

    • Axion
    • Axion Dark Matter Experiment
    • Dark matter halo
    • Minimal Supersymmetric Standard Model
    • Neutralino
    • Scalar field dark matter
    • Weakly interacting massive particles
    • Weakly interacting slender particles

    References

    1. Cassé, M.; Fayet, P. (4–9 July 2005). "Light Dark Matter". 21st IAP Colloquium "Mass Profiles and Shapes of Cosmological Structures". Paris. doi:10.1051/eas:2006072. Bibcode: 2006EAS....20..201C. 
    2. Lee B.W.; Weinberg S. (1977). "Cosmological Lower Bound on Heavy-Neutrino Masses". Physical Review Letters 39 (4): 165–168. doi:10.1103/PhysRevLett.39.165. Bibcode: 1977PhRvL..39..165L. 
    3. Bird, C.; Kowalewski, R.; Pospelov, M. (2006). "Dark matter pair-production in b → s transitions". Mod. Phys. Lett. A 21 (6): 457–478. doi:10.1142/S0217732306019852. Bibcode: 2006MPLA...21..457B. 
    4. Boehm, C.; Fayet, P. (2004). "Scalar Dark Matter candidates". Nuclear Physics B 683 (1–2): 219–263. doi:10.1016/j.nuclphysb.2004.01.015. Bibcode: 2004NuPhB.683..219B. 
    5. Boehm, C.; Fayet, P.; Silk, J. (2004). "Light and Heavy Dark Matter Particles". Physical Review D 69 (10): 101302. doi:10.1103/PhysRevD.69.101302. Bibcode: 2004PhRvD..69j1302B. 
    6. Boehm, C. (2004). "Implications of a new light gauge boson for neutrino physics". Physical Review D 70 (5): 055007. doi:10.1103/PhysRevD.70.055007. Bibcode: 2004PhRvD..70e5007B. 
    7. Beacom, J.F.; Bell, N.F.; Bertone, G. (2005). "Gamma-Ray Constraint on Galactic Positron Production by MeV Dark Matter". Physical Review Letters 94 (17): 171301. doi:10.1103/PhysRevLett.94.171301. PMID 15904276. Bibcode: 2005PhRvL..94q1301B. 
    8. Boehm, C.; Ascasibar, Y. (2004). "More evidence in favour of Light Dark Matter particles?". Physical Review D 70 (11): 115013. doi:10.1103/PhysRevD.70.115013. Bibcode: 2004PhRvD..70k5013B. 

    Further reading

    • Bertone, Gianfranco (2010). Particle Dark Matter: Observations, Models and Searches. Cambridge University Press. pp. 762. ISBN 978-0-521-76368-4. Bibcode: 2010pdmo.book.....B. 



    Retrieved from "https://handwiki.orghttps://handwiki.org/wiki/index.php?title=Physics:Light_dark_matter&oldid=1182955"

    Categories: [Physical cosmology] [Astroparticle physics] [Dark matter] [Particle physics]

    Download as ZWI file | Last modified: 03/18/2022 14:07:35 | 48 views
    ☰ Source: https://handwiki.org/wiki/Physics:Light_dark_matter | License: CC BY-SA 3.0

    ZWI signed:
      Encycloreader by the Knowledge Standards Foundation (KSF) ✓[what is this?]

    ZWI viewer by the EncyclosphereKSF