The predictions of our previous analysis about possible low-mass (mχ < ∼ 50 GeV) relic neutralinos are discussed in the light of some recent results from WIMP direct detection experiments. It is proved that these light neutralinos are quite compatible with the new annual-modulation data of the DAMA Collaboration; our theoretical predictions are also compared with the upper bounds of the CDMS and EDELWEISS Collaborations.PACS numbers: 95.35.+d,11.30.Pb,12.60.Jv,95.30.Cq Searches for neutralinos at colliders have not yet reached the sensitivity required to place a direct lower bound on the neutralino mass m χ . The commonly quoted and employed bound m χ > ∼ 50 GeV is derived from the lower bound on the chargino mass determined at LEP2 (m ± χ > ∼ 100 GeV) under the assumption that the U (1) and SU (2) gaugino masses M 1 and M 2 satisfy the standard relationship M 1 ≃ 1 2 M 2 at the electroweak scale. This hypothesis is a consequence of the assumption that these mass parameters have a common value at the grand unification (GUT) scale.In supersymmetric models with R-parity conservation and no gaugino-unification assumption at the GUT scale, an absolute lower limit on m χ cannot be derived from the lower bound on the chargino mass. Instead, it may be established by applying the upper bound on the Cold Dark Matter (CDM) content in the Universe, Ω CDM ≡ ρ CDM /ρ c , in combination with constraints imposed on the Higgs and supersymmetric parameters by measurements at colliders and other precision experiments (muon g − 2, BR(b → s + γ)). This point was discussed in Refs. [1,2], where a lower bound on the neutralino mass of about 6 GeV was established as a consequence of the recent 2σ C.L. (2) is a consequence the fact that the detection rate has a lower bound induced by the upper limit on Ω CDM h 2 .Recalling that, for neutralino-matter interactions, coherent effects systematically dominate over spindependent ones, the aforementioned properties (1)-(2) are conveniently displayed in terms of the quantity ξσ is the neutralino-nucleon scalar cross-section and ξ is a rescaling factor between the neutralino local matter density ρ χ and the total local dark matter density ρ 0 : ξ ≡ ρ χ /ρ 0 . Following a standard assumption, ξ may be taken asThe supersymmetric model considered in the present paper is an effMSSM scheme at the electroweak scale, with the following independent parameters: M 2 , µ, tan β, m A , mq, ml, A and R ≡ M 1 /M 2 . Notations are as follows: tan β the ratio of the two Higgs v.e.v.'s: tan β ≡< H 0 2 >/< H 0 1 >, µ is the Higgs mixing mass parameter, m A the mass of the CP-odd neutral Higgs boson, mq is a soft-mass common to all squarks, ml is a soft-mass common to all sleptons, A is a common dimensionless trilinear parameter for the third family, Ab = At ≡ Amq and Aτ ≡ Aml (the trilinear parameters for the other families being set equal to zero). Since we are here interested in light neutralinos, we consider values of R lower than its standard value: R GUT ≃ 0.5; for definiteness, we take R in the range: ...
