TY - JOUR
T1 - Testing tidal-torque theory - I. Spin amplitude and direction
AU - Porciani, Cristiano
AU - Dekel, Avishai
AU - Hoffman, Yehuda
PY - 2002/5/11
Y1 - 2002/5/11
N2 - We evaluate the success of linear tidal-torque theory (TTT) in predicting galactic-halo spin using a cosmological N-body simulation with thousands of well-resolved haloes. The protohaloes are identified by tracing today's haloes back to the initial conditions. The TTT predictions for the protohaloes match, on average, the spin amplitudes of the virialized haloes of today, if linear growth is assumed until ∼t0/3, or 55-70 per cent of the halo effective turn-around time. This makes it a useful qualitative tool for understanding certain average properties of galaxies, such as total spin and angular momentum distribution within haloes, but with a random scatter of the order of the signal itself. Non-linear changes in spin direction cause a mean error of ∼50° in the TTT prediction at t0, such that the linear spatial correlations of spins on scales ≥ 1h-1 Mpc are significantly weakened by non-linear effects. This questions the usefulness of TTT for predicting intrinsic alignments in the context of gravitational lensing. We find that the standard approximations made in TTT, including a second-order expansion of the Zel'dovich potential and a smoothing of the tidal field, provide close-to-optimal results.
AB - We evaluate the success of linear tidal-torque theory (TTT) in predicting galactic-halo spin using a cosmological N-body simulation with thousands of well-resolved haloes. The protohaloes are identified by tracing today's haloes back to the initial conditions. The TTT predictions for the protohaloes match, on average, the spin amplitudes of the virialized haloes of today, if linear growth is assumed until ∼t0/3, or 55-70 per cent of the halo effective turn-around time. This makes it a useful qualitative tool for understanding certain average properties of galaxies, such as total spin and angular momentum distribution within haloes, but with a random scatter of the order of the signal itself. Non-linear changes in spin direction cause a mean error of ∼50° in the TTT prediction at t0, such that the linear spatial correlations of spins on scales ≥ 1h-1 Mpc are significantly weakened by non-linear effects. This questions the usefulness of TTT for predicting intrinsic alignments in the context of gravitational lensing. We find that the standard approximations made in TTT, including a second-order expansion of the Zel'dovich potential and a smoothing of the tidal field, provide close-to-optimal results.
KW - Cosmology: theory
KW - Dark matter
KW - Galaxies: formation
KW - Galaxies: haloes
KW - Galaxies: structure
KW - Large-scale structure of Universe
UR - http://www.scopus.com/inward/record.url?scp=0042529398&partnerID=8YFLogxK
U2 - 10.1046/j.1365-8711.2002.05305.x
DO - 10.1046/j.1365-8711.2002.05305.x
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AN - SCOPUS:0042529398
SN - 0035-8711
VL - 332
SP - 325
EP - 338
JO - Monthly Notices of the Royal Astronomical Society
JF - Monthly Notices of the Royal Astronomical Society
IS - 2
ER -