Abstract: The internal deformation of the Appalachian Plateau décollement sheet has a distinctive style involving kink bands and thrusts. In areas where the décollement sheet is underlain by thin salt, the dominant structures are thrusts developed at shallow levels, underlain by a series of steep kink bands that terminate downwards at the Silurian salt décollement. Where the salt is thick, large asymmetrical anticlines developed with hinterland-verging kinks on their back-limbs that deformed the entire supra-salt sequence. In order to understand the constraints on deformation, we have used analytical mechanical modelling based on the maximum strength theorem. The simplified model consists of three layers: two are fluids and the third, intervening layer is a stratified competent material. The model is compressed horizontally and the predictions made are based on the kinematic approach of classical limit analysis. Two modes of deformation are investigated: the thrust and the kink band. The modelling shows that kink bands dominate deformation at large burial depth. At shallower depth and small regional bedding dip, the dominant mode is thrusting. In areas of open folding it is predicted that through-going hinterland-verging kink bands will form at a critical limb dip angle of about 10°. Supplementary material: Technical details of the mechanical theory behind this article are available at https://doi.org/10.6084/m9.figshare.c.3799492

Abstract This guidebook chapter outlines a walking tour that provides an introduction to the geological, archaeological, and historical setting of Pittsburgh, with an emphasis on the use of local and imported geologic materials and resources in the eighteenth and nineteenth centuries. The focus is on downtown Pittsburgh, the low-lying triangle of land where the Monongahela and Allegheny Rivers join to form the Ohio River, and Coal Hill (Mount Washington), the escarpment along the Monongahela River to its south. Topics include the importance of—and concomitant effect of—historic coal use; use of local and imported geologic materials, including dimension stone used for buildings and gravestones, and chert used for gunflints and millstones; the frontier forts built at the site; and the ubiquitous landslides along Coal Hill.

Abstract Johnstown, Pennsylvania, has long been associated with flooding due to major floods in 1889, 1936, and 1977. The most famous of these floods, the Johnstown Flood of 1889, led to more than 2200 deaths and was the result of the catastrophic collapse of the South Fork Dam. This privately owned dam was located on the South Fork of the Little Conemaugh River, ~14 mi (23 km) upstream of Johnstown. The dam changed ownership multiple times since its initial construction and had been improperly rebuilt and maintained after partial breaches. It was the final failure after a wet spring and heavy rainfall that resulted in death and devastation along the Little Conemaugh River valley from South Fork to Johnstown. This field guide presents the history of the South Fork Dam and incorporates recent studies that examined the timing of the flood and failure of the dam itself. The field trip begins at the origin of the flood at the South Fork Dam and largely follows the path of the flood down the valley to Johnstown with stops at sites impacted by the flood wave, as well as sites that demonstrate a response to the flood.

A complex sequence of deformation produced the major central and southern trends of the Appalachian fold-and-thrust belt in the Roanoke recess, Virginia. The incipient recess first experienced the Appalachian-wide stress field, then shifted to far-field effects from incremental counterclockwise rotation of the shortening direction, which resulted in the Central Appalachian fold belt, and then shifted to incremental clockwise rotation, which produced the Southern Appalachian fold-and-thrust belt. We analyzed joints, veins, normal and reverse faults, stylolites, and paleoseismites from Mississippian strata at the structural front of the Southern Appalachian fold-and-thrust belt, and the adjacent Appalachian Plateau west of the recess. We distinguished seven deformational events using orientations, intersection relationships, fault-slip directions, and mineralization histories. Five of these sets represent late Paleozoic deformational events (A1–A5), with shortening directions that show an evolving Alleghanian fold-and-thrust belt in the recess. A1 (shortening trend 085°–265°) is consistent with the previously determined Appalachian-wide stress field and incipient layer-parallel shortening strain in middle Mississippian carbonates. A2 (trend 145°–325°) is a newly recognized event, herein called the Princeton event, which is consistent with dominant orientations of previously determined layer-parallel shortening strain, clastic dikes in Upper Mississippian strata, and stylolites. These far-field effects may mark high-angle basement faulting associated with development of the foredeep bulge during incipient thrusting along the Pulaski thrust system far in the hinterland. A3 (trend 120°–300°) corresponds to initiation of the major Central Appalachian deformation, which resulted in fold-and-thrust belt structures such as the North Mountain fault and Wills Mountain anticline, while A4 (trend 160°–340°) is associated with Southern Appalachian (e.g., St. Clair thrust and Glen Lyn footwall-syncline) structures. A5 (trend 010°–190°) represents late Alleghanian deformation of the Glen Lyn syncline, likely associated with blind thrusting coeval with emplacement of the nearby Pine Mountain thrust sheet. Two post-Alleghanian fracture sets, PA1 (joint trend 150°–330°) and PA2 (joint trend 060°–240°), are orthogonal; PA2 is younger. These joint sets are associated with strike-slip and normal faults that are compatible with some fault-plane solutions from the nearby Giles County seismic zone.