Light Scalar Top Quarks and Supersymmetric Dark Matter

C. Boehm; A. Djouadi; M. Drees

Light Scalar Top Quarks and Supersymmetric Dark Matter

C. Boehm, A. Djouadi, M. Drees

Abstract

A stable neutralino $χ_1^0$, assumed to be the lightest supersymmetric particle, is a favored particle physics candidate for the cosmological Dark Matter. We study co-annihilation of the lightest neutralino with the lighter scalar top quark $\tilde{t}_1$. We show that for natural values of the neutralino mass, $\lsim 300$ GeV, the $χ_1^0 - \tilde{t}_1$ mass difference has to exceed $\sim 10$ to 30 GeV if $χ_1^0$, is to contribute significantly to the Dark Matter. Scenarios with smaller mass splitting, where $\tilde{t}_1$ is quite difficult to detect at collider experiments, are thus cosmologically disfavored. On the other hand, for small $\tilde{t}_1 - χ_1^0$ mass splitting, we show that co--annihilation allows very large neutralino masses, $m_{χ_1^0} \sim 5$ TeV, without ``overclosing'' the Universe.

Light Scalar Top Quarks and Supersymmetric Dark Matter

Abstract

A stable neutralino

, assumed to be the lightest supersymmetric particle, is a favored particle physics candidate for the cosmological Dark Matter. We study co-annihilation of the lightest neutralino with the lighter scalar top quark

. We show that for natural values of the neutralino mass,

GeV, the

mass difference has to exceed

to 30 GeV if

, is to contribute significantly to the Dark Matter. Scenarios with smaller mass splitting, where

is quite difficult to detect at collider experiments, are thus cosmologically disfavored. On the other hand, for small

mass splitting, we show that co--annihilation allows very large neutralino masses,

TeV, without ``overclosing'' the Universe.

Light Scalar Top Quarks and Supersymmetric Dark Matter

Abstract

Light Scalar Top Quarks and Supersymmetric Dark Matter

Abstract

Paper Structure

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