Redshift Evolution of the Fundamental Plane Relation in the IllustrisTNG Simulation

Abstract

We investigate the fundamental plane (FP) evolution of early-type galaxies in the IllustrisTNG-100 simulation (TNG100) from redshift z=0 to z=2. We find that a tight plane relation already exists as early as z=2. Its scatter stays as low as 0.08 dex across this redshift range. Both slope parameters b and c (where R σb Ic with R, σ, and I being the typical size, velocity dispersion, and surface brightness) of the plane evolve mildly since z=2, roughly consistent with observations. The FP residual Res (\,a\,+\,b σ\,+\,c I\,-\, R, where a is the zero point of the FP) is found to strongly correlate with stellar age, indicating that stellar age can be used as a crucial fourth parameter of the FP. However, we find that 4c+b+2=δ, where δ 0.8 for FPs in TNG, rather than zero as is typically inferred from observations. This implies that a tight power-law relation between the dynamical mass-to-light ratio M dyn/L and the dynamical mass M dyn (where M dyn 5σ2R/G, with G being the gravitational constant) is not present in the TNG100 simulation. Recovering such a relation requires proper mixing between dark matter and baryons, as well as star formation occurring with correct efficiencies at the right mass scales. This represents a powerful constraint on the numerical models, which has to be satisfied in future hydrodynamical simulations.