The chemical bonding of different {111} Cu–MgO interfaces obtained
by internal oxidation of (Cu, Mg) alloys at T = 900 °C and for an high
oxygen activity of ao2 = 10−8, is studied by transmission
electron
energy loss spectroscopy (EELS) at high spatial resolution. For polar
{111}
interfaces (Cu and MgO in topotactical or pseudotwin orientation), it is
shown that the terminating lattice plane in magnesia is occupied by oxygen
atoms. An important charge transfer is identified at the interface,
yielding Cu–L ELNES features corresponding to those of Cu1+ (Cu(I))
in its oxide. O–K edge fine structures at the interface are also modified: an edge enlargement and the presence of a low energy shoulder confirm the
bonding of oxygen to Cu1+. Consistent with these results, the Mg–L
edge is never modified compared to the MgO bulk phase. Specifically adapted
to the heterophase interfaces, a spatial difference method, based on
normalised spectra (NSD), is applied to estimate
the relative contribution of the ELNES signal in the interface area. In the
present case of high oxygen activity, the number of copper atoms in the
Cu(I) oxidized state corresponds to a total occupancy of the outermost
metal plane at the interface.