Reproducing the asymptotic behaviour of galaxy rotation curves by a novel constraint in general relativity
Abstract
The cold dark matter paradigm has been posited as the standard explanation for the non-Keplerian behavior of galaxy rotation curves, where for galaxies satisfying the Tully-Fisher relation, the mass of the dark matter halo from a large class of universal dark matter profiles ought to roughly increase linearly with radial distance at large distances, m(r) r/nG (G is the gravitational constant and n is a dimensionless parameter which depends on the amount of baryonic matter M within the galaxy). Despite numerous advances in modeling galaxy formation and evolution, a scientific consensus on the origin of the observed dependence of the dimensionless parameter n = (GMa0)-1/2 on the mass of baryonic matter M within the galaxy (the Tully-Fisher relation), and the connection of the cosmological constant to the parameter a0 (/3)1/2 remains elusive. Here, we show that Einstein Field Equations can be remolded into ∇K\,\,μ = 8π GM*Dμ, where Kμ is a complex Hermitian tensor, Dμ is a covariant derivative and is a complex-valued function. This avails a novel constraint, ∇μ∇Kμ = 0 not necessarily available in Einstein's General Relativity. In the weak-field regime, we can readily reproduce the Tully-Fisher relation using the usual charge-less pressure-less fluid. Moreover, our approach is equivalent to a Ginzburg-Landau theory of n bosons, where the order parameter is normalized as ∫01/a0 dr\,4π r2* = n and 1/a0 (/3)-1/2 is the cut-off length scale comparable to the size of the de Sitter universe. Our investigations provide a framework that reproduces the mass-asymptotic speed relation in galaxies within the cold dark matter paradigm.
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