Southeastern Section - 67th Annual Meeting - 2018

Paper No. 31-6
Presentation Time: 3:30 PM

EVIDENCE FOR TERRANE ACCRETION, LOCALIZED RIFTING AND MAGMATISM FROM THE CRUSTAL VELOCITY STRUCTURE OF THE SOUTHEASTERN UNITED STATES


MARZEN, Rachel E., Columbia University, New York, NY 10027, SHILLINGTON, Donna J., Lamont-Doherty Earth Observatory of Columbia University, 61 Route 9W, Palisades, NY 10964, LIZARRALDE, Dan, Department of Geology and Geophysics, Woods Hole Oceanographic Institution, 266 Woods Hole Rd., MS# 22, Woods Hole, MA 02543 and HARDER, Steven, Dept. of Geological Sciences, University of Texas at El Paso, 500 W. University Ave., El Paso, TX 79968

The crustal structure in the Southeastern United States records a rich tectonic history, including multiple terrane accretion events, the formation of the supercontinent Pangea, widespread magmatism from the Central Atlantic Magmatic Province (CAMP), and crustal thinning before the breakup of Pangea. We use wide-angle refraction seismic data from Lines 1 and 2 of the SUGAR (SUwannee suture and GeorgiA Rift basin) seismic experiment to constrain crustal structure in order to better understand these tectonic events. The 320 and 420 km lines extend from the northwest to the southeast, crossing the Mesozoic rift basins that record crustal thinning prior to the breakup of Pangea and multiple potential suture zones between accreted terranes. We model crustal P-wave velocity structure with reflection/refraction tomography based on refractions through the sediments, crust and mantle and reflections from the base of the sediments, within the crust and the Moho.

To the north on Line 2, we observe high Vp and Vs within the Inner Piedmont and Carolina accreted terranes underlain by a low velocity zone at ~5 km depth. These observations are consistent with metamorphosed terranes accreting onto the Laurentian margin along a low velocity region that represents meta-sedimentary rocks and/or an Appalachian detachment. Additionally, differences in the basin structure, lower crustal velocities, and crustal thickness between Lines 1 and 2 reflect varying extension and magmatism between the two Mesozoic rift segments. Line 1 has thicker and more laterally extensive syn-rift sediments and a more pronounced region of crustal thinning. In contrast, syn-rift sediments along Line 2 are thinner and limited to a couple of smaller basins, and the crust of Line 2 gradually thins towards the coast. The thinned crust beneath Line 1 is characterized by high velocities of >7.0 km/s, which we interpret as mafic intrusions related to rifting or CAMP; in contrast, no evidence of elevated lower crustal velocities is observed on Line 2. Because intrusions into the lower crust increase both lower crustal velocities and crustal thickness, the correspondence of high lower crustal velocities with regions of greater crustal thinning suggests that extension and magmatism were more localized than one would infer based only on variations in crustal thickness.