Light neutralino dark matter in the next-to-minimal supersymmetric standard model

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John F. Gunion,¹ Dan Hooper,² and Bob McElrath¹
¹Department of Physics, University of California, Davis, California 95616, USA
²Department of Physics, Oxford University, Oxford OX1-3RH, United Kingdom and Particle Astrophysics Center, Fermi National Accelerator Laboratory, Batavia, Illinois 60510-0500, USA

Received 25 September 2005; published 19 January 2006

Neutralinodark matter is generally assumed to be relatively heavy, witha mass near the electroweak scale. This does not necessarilyneed to be the case, however. In the next-to-minimal supersymmetricstandard model (NMSSM) and other supersymmetric models with an extendedHiggs sector, a very light CP-odd Higgs boson can naturallyarise making it possible for a very light neutralino toannihilate efficiently enough to avoid being overproduced in the earlyUniverse. In this article, we explore the characteristics of asupersymmetric model needed to include a very light neutralino, 100 MeV<m_{chi-tilde[sub 1][sup 0]}<20 GeV,using the NMSSM as a prototype. We discuss the mostimportant constraints from Upsilon decays, b-->sgamma, B_s-->µ⁺µ^- and the magneticmoment of the muon, and find that a light binoor singlino neutralino is allowed, and can be generated withthe appropriate relic density. It has previously been shown thatthe positive detection of dark matter claimed by the DAMAcollaboration can be reconciled with other direct dark matter experimentssuch as CDMS II if the dark matter particle israther light, between about 6 and 9 GeV. A singlino orbinolike neutralino could easily fall within this range of masseswithin the NMSSM. Additionally, models with sub-GeV neutralinos may becapable of generating the 511 keV gamma-ray emission observed from thegalactic bulge by the INTEGRAL/SPI experiment. We also point outmeasurements which can be performed immediately at CLEO, BABAR, andBelle using existing data to discover or significantly constrain thisscenario.

URL:	http://link.aps.org/doi/10.1103/PhysRevD.73.015011
DOI:	10.1103/PhysRevD.73.015011
PACS:	12.60.Jv; 14.80.Cp; 95.35.+d 12.60.Jv Supersymmetric unified models 14.80.Cp Non-standard-model Higgs bosons 95.35.+d Dark matter (stellar, interstellar, galactic, and cosmological) YEAR: 2006
KEYWORDS:	minimal supersymmetric standard model, dark matter, cosmology, electromagnetic decays, Higgs bosons, CP invariance, meson leptonic decay, lepton magnetic moment, electroweak theories, sparticles, B mesons