Galaxy halo expansions: a new biorthogonal family of potential-density pairs
arXiv:1802.03350 · doi:10.1093/mnras/sty296
Abstract
Efficient expansions of the gravitational field of (dark) haloes have two main uses in the modelling of galaxies: first, they provide a compact representation of numerically-constructed (or real) cosmological haloes, incorporating the effects of triaxiality, lopsidedness or other distortion. Secondly, they provide the basis functions for self-consistent field expansion algorithms used in the evolution of $N$-body systems. We present a new family of biorthogonal potential-density pairs constructed using the Hankel transform of the Laguerre polynomials. The lowest-order density basis functions are double-power-law profiles cusped like $Ï\sim r^{-2 + 1/α}$ at small radii with asymptotic density fall-off like $Ï\sim r^{-3 -1/(2α)}$. Here, $α$ is a parameter satisfying $α\ge 1/2$. The family therefore spans the range of inner density cusps found in numerical simulations, but has much shallower -- and hence more realistic -- outer slopes than the corresponding members of the only previously-known family deduced by Zhao (1996) and exemplified by Hernquist & Ostriker (1992). When $α=1$, the lowest-order density profile has an inner density cusp of $Ï\sim r^{-1}$ and an outer density slope of $Ï\sim r^{-3.5}$, similar to the famous Navarro, Frenk & White (1997) model. For this reason, we demonstrate that our new expansion provides a more accurate representation of flattened NFW haloes than the competing Hernquist-Ostriker expansion. We utilize our new expansion by analysing a suite of numerically-constructed haloes and providing the distributions of the expansion coefficients.
MNRAS, in press