Highly oriented pyrolitic graphite was irradiated with 1.8 MeV electrons at 45 degrees and nea r-grazing (86 degrees) angles of incidence. For doses up to 10(16) cm(-2) electrons the surface of the samples subjected to 45 degrees incidence, observed by both STM and atomic force microscopy (AFM) remained the same as the original sample showing only the usual periodic atomic corrugation, with an atomic spacing of 0.246 nm. For near-grazing incidence, at a dose of 5 x 10(12) cm(-2) electrons, features of nanometre size are observed, some elongated along the direction of the beam incidence. These are attributed to the effects of single electron-carbon interactions in the top surface layers. At a dose of 5 x 10(14) cm(-2) electrons (near grazing incidence) both STM and AFM observations show an anomalously large (period 2.5-17 nm) superperiodicity superimposed on the normal 0.246 nm atomic spacing of graphite. This Moire-like pattern suggests that the corrugations are electronic as well as topographic in origin. We propose that near-grazing incidence electron irradiation causes break-up of the surface layers into fragments, largely retaining six-fold atomic rings, that rotate by a small angle resulting in the observed pattern due to interaction with deeper bulk-structure layers.