Origin of sheet structure, 1. Morphology and boundary conditions

Sheet structure, or large-scale exfoliation, is the division of a rock mass into lenses, plates or “sheets” approximately parallel to the earth's surface. Sheet fractures, which separate the plates, are characterized by surface markings resembling those formed during the brittle fracture of metals, glass and ceramics and those on joints in rock. Lineations, or hackle marks, parallel to the direction of fracture propagation, are common. Branching occurs during propagation so that the fractures appear as many echelon segments in profile. The opposing surfaces of sheet fractures observed in quarry walls and natural exposures are typically in contact. Damage, if any, to rock adjacent to sheet fractures is generally limited to a zone less than one centimeter wide. Sheets tend to parallel preferred orientations of microcracks in many rock masses. Most sheets that are exposed today are of prehistoric origin, but in some rock masses, such as Chelmsford granite in Massachusetts, new sheets continue to form.

Sheet structure forms in environments of high differential stress, dominated by large-scale compression parallel to an exposed rock surface. In parts of the Chelmsford granite the magnitude of this compression is greater than 30 MPa in the zone of sheeting. High differential stresses near the ground surface can result from several natural agents, including contemporary tectonic forces, vertical unloading of a rock mass that formed at depth under high triaxial compression, and suppression of expansion that would otherwise result from temperature increases or chemical alteration of the rock. Exfoliation of boulders during forest fires and spheroidal weathering of boulders appears to occur under similar states of stress, although the agents responsible for the stresses differ.