Abstract

We consider $N\\times N$ Hermitian random matrices with i.i.d. entries. The matrix\n is normalized so that the average spacing between consecutive eigenvalues is of order\n $1/N$. We study the connection between eigenvalue statistics on microscopic energy scales\n $\\eta\\ll1$ and (de)localization properties of the eigenvectors. Under suitable assumptions\n on the distribution of the single matrix elements, we first give an upper bound on the\n density of states on short energy scales of order $\\eta \\sim\\log N/N$. We then prove that\n the density of states concentrates around the Wigner semicircle law on energy scales\n $\\eta\\gg N^{-2/3}$. We show that most eigenvectors are fully delocalized in the sense that\n their $\\ell^p$-norms are comparable with $N^{{1}/{p}-{1}/{2}}$ for $p\\ge2$, and we obtain\n the weaker bound $N^{{2}/{3}({1}/{p}-{1}/{2})}$ for all eigenvectors whose eigenvalues are\n separated away from the spectral edges. We also prove that, with a probability very close\n to one, no eigenvector can be localized. Finally, we give an optimal bound on the second\n moment of the Green function.