Tip orbitals and the atomic corrugation of metal surfaces in scanning tunneling microscopy

When atomic resolution is achieved, the scanning tunneling microscope (STM) image of a dense metal surface shows a giant amplitude, i.e., between one and two orders of magnitude larger than expected from an s-wave tip. To date, no satisfactory explanation has been given. Using our earlier nonperturbative formalism for the tunnel current, we reconsider the corrugation problem with a single atom tip having s, p, or d orbitals, or a combination. Particular emphasis is on the value of the corrugation as a function of the tunnel resistance Delta(l,m)(R). Results show that the corrugation, observed over the wide range (10(5)-10(8)Ohm), is inconsistent by nearly two orders of magnitude with the s-orbital theory, and by one order of magnitude with the d(z2) one. We also can put aside tip-surface interactions. Tip states, such as p(z) and d(x2) give basically s-wave behavior in Delta(l,m)(R). However, those with axial symmetry, such as d(xz) + id(yz) and having a nodal line orthogonal to the surface, give an enhanced corrugation. Finally, in tip states with a nodal plane, such as d(x2-y2) the enhancement effect is much more pronounced. Identical results are obtained by considering separately the nearly free electron model, and a new method of atomic orbital superposition, for the metal surface.