Noncovariance at low accelerations as a route to MOND

Abstract

MOND has limelighted the fact that Newtonian dynamics (ND) and general relativity (GR) have not been verified at accelerations below MOND's a0. In particular, we do not know that all the principles underlying ND or GR apply below a0. I discuss possible breakdown of general covariance (GC) in this limit. This resonates well with MOND, which hinges on accelerations. Relaxing GC affords more freedom in constructing MOND theories. I exemplify this with a simplified theory whose gravitational Lagrangian is LM M-2F(M2R), where R= gμ (γμλλγ-γμλ λγ)/2. γμ is the Levi-Civita connection of a metric, gμ, and M=c2/a0 is the MOND length. Requiring F(z)→ z+ζ, for z 1 gives GR with a cosmological constant ζ c-4a02 for high accelerations. In the MOND limit F'(z 1) z1/2. In the nonrelativistic limit the metric is of the form gμ≈ ημ-2φδμ, as in GR, but the potential φ solves a MOND, nonlinear Poisson analog. This form of gμ also produces gravitational lensing as in GR only with the MOND potential. I show that this theory is a fixed-gauge expression of BIMOND, with the auxiliary metric constrained to be flat. The latter theory is thus a covariantized version of the former a-la St\"uckelberg. This theory is also a special case of so-called f(Q) theories -- aquadratic generalizations of `symmetric, teleparallel GR', which are, in turn, also equivalent to constrained BIMOND-type theories. (Abridged.)