Non-zero trilinear parameter in the mSUGRA model - dark matter and collider signals at Tevatron and LHC

TL;DR

This paper explores the effects of non-zero trilinear parameters in the mSUGRA model, revealing new dark matter annihilation channels and distinctive collider signatures at Tevatron and LHC, especially with light squarks and gluinos.

Contribution

It demonstrates that relaxing the A_0=0 assumption opens new viable parameter space with observable collider signals and dark matter relic density explanations.

Findings

Multiple processes contribute to dark matter relic density.

Large squark-gluino events produce distinctive tau signatures at LHC.

Non-zero A_0 allows lighter sparticles consistent with experimental bounds.

Abstract

Phenomenologically viable and interesting regions of parameter space in the minimal super-gravity (mSUGRA) model with small $m_0$ and small $m_{1/2}$ consistent with the WMAP data on dark matter relic density and the bound on the mass of the lightest Higgs scalar $ m_h>$ 114 GeV from LEP2 open up if the rather adhoc assumption $A_0$=0, where $A_0$ is the common trilinear soft breaking parameter, employed in most of the existing analyses is relaxed. Since this region corresponds to relatively light squarks and gluinos which are likely to be probed extensively in the very early stages of the LHC experiments, the consequences of moderate or large negative values of $A_0$ are examined in detail. We find that in this region several processes including lightest supersymmetric particle (LSP) pair annihilation, LSP - lighter tau slepton (${\tilde \tau}_1$) coannihilation and LSP - lighter top squark (${\tilde t}_1$) coannihilation contribute to the observed dark matter relic density. %\sout{The possibility that a relic density producing ${\tilde t}_1$ can be %observed at the current experiments at the Tevatron is wide open.} The possibility that a ${\tilde t}_1$ that can participate in coannihilation with the lightest neutralino to satisfy the WMAP bound on relic density and at the same time be observed at the current experiments at the Tevatron is wide open. At the LHC a large number of squark - gluino events lead to a very distinctive semi-inclusive signature $\tau^\pm$+X$_\tau$ (anything without a tau lepton) with a characteristic size much larger than $e^\pm$+X$_e$ or $\mu^\pm$+X$_\mu$ events.