Abstract

Direct electronic structure measurements of a variety of colossal magnetoresistive (CMR) oxides show the presence of a pseudogap at the Fermi energy ${E}_{F}$ which drastically suppresses the electron spectral function at ${E}_{F}.$ The pseudogap is a strong function of the layer number of the samples (sample dimensionality) and is strongly temperature dependent, with the changes beginning at the ferromagnetic transition temperature ${T}_{c}.$ These trends are consistent with the major transport trends of the CMR oxides, implying a direct relationship between the pseudogap and transport, including the ``colossal'' conductivity changes which occur across ${T}_{c}.$ The k dependence of the temperature-dependent effects indicates that the pseudogap observed in these compounds is not due to the extrinsic effects proposed by Joynt.