Variations in exhumation level and uplift rate along the oblique-slip Alpine fault, central Southern Alps, New Zealand

We use geophysical and geological data from the Southern Alps to explore the relationship between plate motions and crustal structure on the geomorphology, exhumation state, and deformation style of rocks uplifted along a major oblique-slip fault. A similar to 50-km-long segment of the Southern Alps has a higher uplift rate, more relief, deeper exhumation, and a narrower width than surrounding regions. There, the delaminated, east-tilted crust of the Pacific Plate yields the youngest, late Cenozoic thermochronometric ages. Contours for fission-track, Ar/Ar and K-Ar ages on several different minerals define an asymmetrically nested pattern of ages that increase away from the western side of the central Southern Alps. Eleven new 40Ar/39Ar samples of hornblende from the hanging wall of the Alpine fault indicate that lower crustal rocks exhumed from > 500 degrees C in the late Cenozoic are confined to a 20-km-long culmination at the southern end of the central Southern Alps. Ages as low as 3-5 Ma imply time-integrated vertical exhumation rates as high as similar to 6-9 mm/yr. This is the only part of this 5-8 Ma range that may have achieved exhumational steady state. Remnant plugs of the original crustal hanging wall ramp are apparently preserved outside the central Alps, implying < 70 km of fault convergence there. 40Ar/39Ar age trends for hornblende near the Alpine fault suggest that horizontal surfaces in the lower crust in the Pacific Plate have been overturned by reverse-slip ductile shearing across a zone of distributed deformation that extends similar to 2 km beyond the similar to 1-km-thick, basal mylonite zone. At the broadest, orogen scale, higher uplift rates throughout the central Southern Alps may be related to a rheologically controlled increase in the convergent velocity of points to the cast of the Alpine fault, associated with a strengthening of the Pacific crust. At a more local scale, maximum rates of uplift are inferred to occur near Franz-Josef and Fox Glaciers because the Alpine fault steepens at depth. Structural data suggests that its footwall ramp is curved, and that the fault's dip steepens by 15-20 degrees relative to its attitude farther to the south. This 10-20-km-long restraining bend may enhance local rates of rock uplift near Franz Josef and Fox Glaciers. Contemporary normal stress and shear resistance may also be increased on this part of the Alpine fault, helping to explain the central region's quiet historic seismicity and apparently strongly locked nature.