We have measured the clustering of 0.30 < z < 0.90 red galaxies and constrained models of the evolution of large-scale structure using the initial 1.2 deg~2 data release of the NOAO Deep Wide-Field Survey (NDWFS). The area and B_WRI passbands of the NDWFS allow samples of approx> 10~3 galaxies to be selected as a function of spectral type, absolute magnitude, and photometric redshift. Spectral synthesis models can be used to predict the colors and luminosities of a galaxy population as a function of redshift. We have used PEGASE2 models, with exponentially declining star formation rates, to estimate the observed colors and luminosity evolution of galaxies and to connect, as an evolutionary sequence, related populations of galaxies at different redshifts. A red galaxy sample, with present-day rest-frame Vega colors of B_W-R > 1.44, was chosen to allow comparisons with the 2dF Galaxy Redshift Survey and Sloan Digital Sky Survey. We find the spatial clustering of red galaxies to be a strong function of luminosity, with r_0 increasing from 4.4 +- 0.4 h~(-1) Mpc at M_R - 5 log h ≈ -20.0 to 11.2 +- 1.0 h~(-1) Mpc at M_R - 5 log h ≈ -22.0. Clustering evolution measurements using samples where the rest-frame selection criteria vary with redshift, including all deep single-band magnitude limited samples, are biased because of the correlation of clustering with rest-frame color and luminosity. The clustering of -21.5 < M_R - 5 log h < -20.5, B_W-R > 1.44 galaxies exhibits no significant evolution over the redshift range observed with r_0 = 6.3 +- 0.5 h~(-1) Mpc in comoving coordinates. This is consistent with recent ACDM models in which the bias of L~* galaxies undergoes rapid evolution and r_0 evolves very slowly at z < 2.
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