BlueTides simulation: establishing black hole-galaxy relations at high-redshift

Abstract

The scaling relations between the mass of supermassive black holes (M) and host galaxy properties (stellar mass, M, and velocity dispersion, σ), provide a link between the growth of black holes (BHs) and that of their hosts. Here we investigate if and how the BH-galaxy relations are established in the high-z universe using BlueTides, a high-resolution large volume cosmological hydrodynamic simulation. We find the M-M and M-σ relations at z=8: 10(M) = 8.25 + 1.10 \ 10(M/1011M) and 10(M) = 8.35 + 5.31 \ 10(σ/200kms-1) at z=8, both fully consistent with the local measurements. The slope of the M-σ relation is slightly steeper for high star formation rate and M galaxies while it remains unchanged as a function of Eddington accretion rate onto the BH. The intrinsic scatter in M-σ relation in all cases (ε 0.4) is larger at these redshifts than inferred from observations and larger than in M-M relation (ε 0.14). We find the gas-to-stellar ratio f=M gas/M in the host (which can be very high at these redshifts) to have the most significant impact setting the intrinsic scatter of M-σ. The scatter is significantly reduced when galaxies with high gas fractions (ε = 0.28 as f<10) are excluded (making the sample more comparable to low-z galaxies); these systems have the largest star formation rates and black hole accretion rates, indicating that these fast-growing systems are still moving toward the relation at these high redshifts. Examining the evolution (from z=10 to 8) of high mass black holes in M-σ plane confirms this trend.