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Time-Dependent Vacuum Energy Induced by D-Particle Recoil

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 Added by Dr N. Mavromatos
 Publication date 1998
  fields Physics
and research's language is English




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We consider cosmology in the framework of a `material reference system of D particles, including the effects of quantum recoil induced by closed-string probe particles. We find a time-dependent contribution to the cosmological vacuum energy, which relaxes to zero as $sim 1/ t^2$ for large times $t$. If this energy density is dominant, the Universe expands with a scale factor $R(t) sim t^2$. We show that this possibility is compatible with recent observational constraints from high-redshift supernovae, and may also respect other phenomenological bounds on time variation in the vacuum energy imposed by early cosmology.



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