Treffer: Prospects for detecting supersymmetric dark matter in the Galactic halo

Title:
Prospects for detecting supersymmetric dark matter in the Galactic halo
Authors:
SPRINGEL, V, WHITE, S. D. M, FRENK, C. S, NAVARRO, J. F, JENKINS, A, VOGELSBERGER, M, WANG, J, LUDLOW, A, HELMI, A
Source:
Nature (London). 456(7218):73-76
Publisher Information:
London: Nature Publishing Group, 2008.
Publication Year:
2008
Physical Description:
print, 30 ref
Original Material:
INIST-CNRS
Subject Terms:
Multidisciplinary, Multidisciplinaire, Sciences exactes et technologie, Exact sciences and technology, Terre, ocean, espace, Earth, ocean, space, Astronomie, Astronomy, Astronomie fondamentale et astrophysique. Instrumentation, techniques, et observations astronomiques, Fundamental astronomy and astrophysics. Instrumentation, techniques, and astronomical observations, Matière sombre (stellaire, interstellaire, galactique et cosmologique), Dark matter (stellar, interstellar, galactic, and cosmological), Systèmes stellaires. Objets et systèmes galactiques et extragalactiques. L'univers, Stellar systems. Galactic and extragalactic objects and systems. The universe, Caractéristiques et propriétés de la galaxie, Characteristics and properties of the milky way, Bras spiraux et disque galactique, Spiral arms and galactic disk, Détectabilité, Detectability, Detectabilidad, Galaxies compagnons, Satellite galaxies, Galaxias satélite, Galaxies naines, Dwarf galaxies, Halo galactique, Galactic halos, Matière sombre froide, Cold dark matter, Materia oscura fría, Matière sombre, Dark matter, Modèle, Models, Modelo, Particule supersymétrique, Sparticles, Particule élémentaire, Elementary particles, Simulation numérique, Digital simulation, Structure petite échelle, Small scale structure, Estructura pequeña escala, Voie lactée, Milky Way
Document Type:
Fachzeitschrift Article
File Description:
text
Language:
English
Author Affiliations:
Max Planck Institute for Astrophysics, Karl-Schwarzschild-Strasse 1, 85740 Garching, Germany
Ιnstitute for Computational Cosmology, Department of Physics, University of Durham, South Road, Durham DH1 3LE, United Kingdom
Department of Physics and Astronomy, University of Victoria, Victoria, British Columbia V8P 5C2, Canada
Department of Astronomy, University of Massachusetts, Amherst, Massachusetts 01003-9305, United States
Kapteyn Astronomical Institute, University of Groningen, PO Box 800, 9700 AV Groningen, Netherlands
ISSN:
0028-0836
Access URL:
http://pascal-francis.inist.fr/vibad/index.php?action=search&terms=20806397
Rights:
Copyright 2009 INIST-CNRS
CC BY 4.0
Sauf mention contraire ci-dessus, le contenu de cette notice bibliographique peut être utilisé dans le cadre d’une licence CC BY 4.0 Inist-CNRS / Unless otherwise stated above, the content of this bibliographic record may be used under a CC BY 4.0 licence by Inist-CNRS / A menos que se haya señalado antes, el contenido de este registro bibliográfico puede ser utilizado al amparo de una licencia CC BY 4.0 Inist-CNRS
Notes:
Astronomy
Accession Number:
edscal.20806397
Database:
PASCAL Archive

Weitere Informationen

Dark matter is the dominant form of matter in the Universe, but its nature is unknown. It is plausibly an elementary particle, perhaps the lightest supersymmetric partner of known particle species1. In this case, annihilation of dark matter in the halo of the Milky Way should produce γ-rays at a level that may soon be observable2,3. Previous work has argued that the annihilation signal will be dominated by emission from very small clumps4,5(perhaps smaller even than the Earth), which would be most easily detected where they cluster together in the dark matter haloes of dwarf satellite galaxies'. Here we report that such small-scale structure will, in fact, have a negligible impact on dark matter detectability. Rather, the dominant and probably most easily detectable signal will be produced by diffuse dark matter in the main halo of the Milky Way7,8. If the main halo is strongly detected, then small dark matter clumps should also be visible, but may well contain no stars, thereby confirming a key prediction of the cold dark matter model.