Dark Matter from a Dark Connection

TL;DR

This paper proposes that a non-Riemannian dark connection in the affine structure of spacetime can serve as a natural dark matter candidate, linking modified gravity concepts with particle dark matter models.

Contribution

It introduces a novel dark connection in affine geometry as a dark matter candidate and demonstrates how it can be reinterpreted as scalar or vector dark matter models compatible with cosmological observations.

Findings

Dark connection leads to a conserved symmetric tensor acting as dark matter.

Models can reproduce relic density and fit inflationary data.

Fuzzy Dark Matter and Planckian Interacting Dark Matter scenarios are naturally incorporated.

Abstract

In the first part of this note, we observe that a non-Riemannian piece in the affine connection (a "dark connection") leads to an algebraically determined, conserved, symmetric 2-tensor in the Einstein field equations that is a natural dark matter candidate. The only other effect it has, is through its coupling to standard model fermions via covariant derivatives. If the local dark matter density is the result of a background classical dark connection, these Yukawa-like mass corrections are minuscule ($\sim 10^{-31}$ eV for terrestrial fermions) and {\em none} of the tests of general relativity or the equivalence principle are affected. In the second part of the note, we give dynamics to the dark connection and show how it can be re-interpreted in terms of conventional dark matter particles. The simplest way to do this is to treat it as a composite field involving scalars or vectors. The (pseudo-)scalar model naturally has a perturbative shift-symmetry and leads to versions of the Fuzzy Dark Matter (FDM) scenario that has recently become popular (eg., arXiv:1610.08297) as an alternative to WIMPs. A vector model with a ${\cal Z}_2$-parity falls into the Planckian Interacting Dark Matter (PIDM) paradigm, introduced in arXiv:1511.03278. It is possible to construct versions of these theories that yield the correct relic density, fit with inflation, and are falsifiable in the next round of CMB experiments. Our work is an explicit demonstration that the meaningful distinction is not between gravity modification and dark matter, but between theories with extra fields and those without.