The PAMELA excess from neutralino annihilation in the NMSSM

TL;DR

This paper explores whether the PAMELA cosmic ray positron excess can be explained by neutralino annihilation within the NMSSM, predicting specific collider signatures and spectral features.

Contribution

It identifies a unique NMSSM parameter space where neutralino annihilation explains PAMELA data, with specific mass and particle properties, and discusses related spectral and collider predictions.

Findings

Neutralino mass around 160 GeV explains PAMELA excess.

A very light pseudoscalar (<1 GeV) is predicted.

Positron spectrum will turn over at ~70 GeV.

Abstract

We examine whether the cosmic ray positron excess observed by PAMELA can be explained by neutralino annihilation in the Next-to-Minimal Supersymmetric Standard Model (NMSSM). The main dark matter annihilation products are the lightest CP-even scalar h1 plus the lightest CP-odd scalar a1, with the a1 decaying into two muons. The energetic positrons needed to explain PAMELA are thus obtained in the NMSSM simply from kinematics. The required large annihilation cross section is obtained from an s-channel resonance with the heavier CP-odd scalar a2. Various experiments constrain the PAMELA-favored NMSSM parameter space, including collider searches for a light a1. These constraints point to a unique corner of the NMSSM parameter space, having a lightest neutralino mass around 160 GeV and a very light pseudoscalar mass less than a GeV. A simple parameterized formula for the charge-dependent solar modulation effects reconciles the discrepancy between the PAMELA data and the estimated background at lower energies. We also discuss the electron and gamma ray spectra from the Fermi LAT observations, and point out the discrepancy between the NMSSM predictions and Fermi LAT preliminary results and possible resolution. An NMSSM explanation of PAMELA makes three striking and uniquely correlated predictions: the rise in the PAMELA positron spectrum will turn over at around 70 GeV, the dark matter particle mass is less than the top quark mass, and a light sub-GeV pseudoscalar will be discovered at colliders.