Fermion Condensate Inflation, Dynamical Waterfall Mechanism and Primordial Black Holes
Stephon Alexander, Pisin Chen, Jinglong Liu, Antonino Marciano, Misao Sasaki + 1 more
TLDR
This paper proposes fermion condensate inflation, eliminating extra scalar fields, and explains primordial black hole formation via a dynamical waterfall mechanism.
Key contributions
- Fermion condensate inflation uses four-fermion interactions and spacetime torsion, removing the need for new scalar fields.
- The model features a dynamical waterfall mechanism, resembling hybrid inflation, with an axial chemical potential ending inflation.
- Non-topological solitons (Q-balls) form during the waterfall phase, acting as seeds for primordial black holes (PBHs).
- Intrinsically linked to Chern-Simons gravity, implying a parity-violating universe.
Why it matters
This model offers a novel explanation for inflation and primordial black hole formation without requiring new Standard Model scalar fields. Its connection to Chern-Simons gravity predicts a parity-violating universe. Observational tests via PBH dark matter and parity-violation signatures could validate this framework.
Original Abstract
Fermion condensate inflation, where inflation emerges from four-fermion interactions induced by spacetime torsion, removes the need for additional scalar fields beyond the Standard Model. In this framework, the fermion field can be decomposed into two distinguished sectors, each giving rise to bound states. After integrating out fermions, the bound fields play the roles of the inflaton and the auxiliary fields, resembling hybrid inflation with a waterfall mechanism. The inclusion of an axial chemical potential naturally introduces a mechanism to end inflation and trigger instant preheating. During the waterfall phase, the effective potential of the fermion condensate supports the formation of non-topological solitons such as Q-balls, which act as seeds of primordial black holes. This model is intrinsically connected to Chern-Simons gravity, which implies a parity-violating universe. Consequently, both the primordial black hole (PBH) dark-matter abundance and parity-violation signatures could provide observational tests of the model.
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