Zero bias anomaly in the density of states of low-dimensional metals

We consider the effect of Coulomb interactions on the average density of states (DOS) of disordered low-dimensional metals for temperatures T and frequencies w smaller than the inverse elastic life-time 1/tau(0). Using the fact that long-range Coulomb interactions in two dimensions (2d) generate ln(2)-singularities in the DOS v(w) but only ln-singularities in the conductivity a(w), we can re-sum the most singular contributions to the average DOS via a simple gauge-transformation. If lim(w-->0) sigma(w) > 0, then a metallic Coulomb gap v(w) proportional to \w\/e(4) appears in the DOS at T = 0 for frequencies. below a certain crossover frequency Omega(2) which depends on the value of the DC conductivity sigma(0). Here, -e is the charge of the electron. Naively adopting the same procedure to calculate the DOS in quasi Id metals, we find v(w) proportional to (\w\/Omega(1))(1/2) exp(-Omega(1)/\w\) at T = 0, where Omega(1) is some interaction-dependent frequency scale. However, we argue that in quasi Id the above gauge-transformation method is on less firm grounds than in 2d. We also discuss the behavior of the DOS at finite temperatures and give numerical results for the expected tunneling conductance that can be compared with experiments.