MOND fiducial specific angular momentum of disc galaxies

TL;DR

This paper derives a fiducial specific angular momentum (SAM) for galaxies based on MOND, explaining its role in galaxy dynamics, evolution, and the formation of different galaxy types, with implications for galaxy scaling relations.

Contribution

It introduces a MOND-based fiducial SAM formula and explores its implications for galaxy evolution and morphology, providing a theoretical framework for galaxy angular momentum.

Findings

Derivation of a MOND fiducial specific angular momentum formula.

Relation between SAM and galaxy surface density and size.

Predictions for galaxy evolution based on initial SAM relative to the fiducial value.

Abstract

It is pointed out that MOND defines a fiducial specific angular momentum (SAM) for a galaxy of total (baryonic) mass $\mathcal{M}$: $j_M(\mathcal{M})\equiv\mathcal{M}^{3/4}(G^3/a_0)^{1/4}\approx 383(\mathcal{M}/10^{10}M_\odot)^{3/4}{\rm kpc~km/s}$. It plays important roles in disc-galaxy dynamics and evolution: It underlies scaling relations in virialized galaxies that involve their angular-momentum. I show that the disc SAM should be $j_D\approx[\langle r\rangle/r_M(\mathcal{M})]j_M(\mathcal{M})=[\Sigma_M/\langle \Sigma\rangle]^{1/2}j_M(\mathcal{M})$, with $\langle r\rangle$ the mean radius of the disc, $\langle \Sigma\rangle=\mathcal{M}/2\pi\langle r\rangle^2$ some mean surface density of the galaxy, $r_M=(\mathcal{M} G/a_0)^{1/2}$ is the MOND radius of the galaxy, and $\Sigma_M=a_0/2\pi G$ is the (universal) MOND surface density. So, e.g., for a fixed $\langle \Sigma\rangle$, $j_D\propto \mathcal{M}^{3/4}$, while for a fixed $\langle r\rangle$, $j_D\propto \mathcal{M}^{1/4}$. Furthermore, $j_M(\mathcal{M})$ is a reference predictor of the type of galaxy a protogalaxy will settle into, if it evolves in isolation: A protogalaxy of mass $\mathcal{M}$, and SAM $j\gg j_M(\mathcal{M})$ should settle into a low-surface-density disc -- with mean acceleration $\langle a\rangle/a_0\approx j_M/j\ll 1$. While a protogalaxy with $j\lesssim j_M(\mathcal{M})$ should end up with a disc of mass $\mathcal{M}_D\approx j\mathcal{M}/j_M(\mathcal{M})$, having a SAM $j_D\approx j_M(\mathcal{M})$, which is tantamount to $\langle a\rangle\approx a_0$ (i.e., at the `Freeman limit'); it should also develop a low-SAM bulge, taking up the rest of the mass $\mathcal{M}_B\approx\mathcal{M}-\mathcal{M}_D$.