Lynn Glover scite author profile

Multichannel and wide‐angle seismic data collected off Virginia during the 1990 EDGE Mid‐Atlantic seismic experiment provide the most detailed image to date of the continent‐ocean transition on the U.S. Atlantic margin. Multichannel data were acquired using a 10,800 in3 (177 L) airgun array and 6‐km‐long streamer, and coincident wide‐angle data were recorded by ten ocean bottom seismic instruments. A velocity model constructed by inversion of wide‐angle and vertical‐incidence travel times shows strong lateral changes in deep‐crustal structure across the margin. Lower‐crustal velocities are 6.8 km/s in rifted continental crust, increase to 7.5 km/s beneath the outer continental shelf, and decrease to 7.0 km/s in oceanic crust. Prominent seaward‐dipping reflections within basement lie within layers of average velocity 6.3–6.5 km/s, consistent with their interpretation as basalts extruded during rifting. The high‐velocity lower crust and seaward‐dipping reflections comprise a 100‐km‐wide, 25‐km‐thick ocean‐continent transition zone that consists almost entirely of mafic igneous material accreted to the margin during continental breakup. The boundary between rifted continental crust and this thick igneous crust is abrupt, occupying only about 20 km of the margin. Appalachian intracrustal reflectivity largely disappears across this boundary as velocity increases from 5.9 km/s to >7.0 km/s, implying that the reflectivity is disrupted by massive intrusion and that very little continental crust persists seaward of the reflective crust. The thick igneous crust is spatially correlated with the East Coast magnetic anomaly, implying that the basalts and underlying intrusives cause the anomaly. The details of the seismic structure and lack of independent evidence for an appropriately located hotspot in the central Atlantic imply that nonplume processes are responsible for the igneous material.

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Geology of the Coamo area, Puerto Rico, and its relation to the volcanic arc-trench association

Glover¹

1971

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___ ________________________________________ Introduction. _ _____________________________________ Petrographic methods ___________________________ Definitions of some terms._______________________ Acknowledgments ______________________________ General geologic setting.____________________________ Cretaceous rocks.__________________________________ Pre-Robles rocks_ ______________________________ Robles Formation._____________________________ Bedded volcaniclastic rocks__________________ Rio Maton Limestone Member.______________ Lapa Lava Member._ ______________________ Las Tetas Lava Member.____ ______________ Some chemical peculiarities of the lavas____ __ Age ______________________________________ Source and conditions of deposition__ ________ Cariblanco Formation-__________________________ Volcaniclastic rocks_________________________ Conglomerate: mixtures of gravel, ash, and reworked pyroclastics_ ____________ Gravel. ___________________________ Conglomerate matrix and coarse volcaniclastic strata _________________ Mudstone, chert, and tuff___________.

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Deep seismic reflection data of EDGE U.S. mid-Atlantic continental-margin experiment: Implications for Appalachian sutures and Mesozoic rifting and magmatic underplating

Sheridan

Musser

Glover

et al. 1993

Geol

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A geophysical study of the Earth's crust in central Virginia: Implications for Appalachian crustal structure

Pratt¹,

Çoruh²,

Costain³

et al. 1988

J. Geophys. Res.

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A regional seismic reflection line (I‐64) across the Virginia Piedmont has provided a stacked section suitable for an integrated interpretation of geophysical data in the region. A highly reflective upper crust, an allochthonous Blue Ridge Province, underlying thrust sheets including the Blue Ridge master decollement, and a basal decollement at a depth of about 9 km (3 s) are confirmed on the seismic data. Immediately east of the Blue Ridge Province, Appalachian structures plunge to as much as 12 km (4 s) depth. The Evington Group, Hardware terrane, and Chopawamsic metavolcanic rocks (Carolina terrane) crop out in the Piedmont Province, and numerous eastward dipping reflections originate from these rocks in the subsurface. These eastward dipping reflectors overlie a gently west dipping (10°–15°), highly reflective zone that varies in depth from 1.5 s (4.5 km) beneath the Goochland terrane to 4 s (12 km) beneath the rocks of the Evington Group. Some of the overlying eastward dipping reflections apparently root in this zone. The zone may include decollement surfaces along which the overlying rocks were transported. Relatively few reflections originate from within autochthonous Grenville basement at the western end of the profile. The Goochland granulite terrane is interpreted to be a westward thrust nappe structure that has overridden a portion of the Chopawamsic metavolcanic rocks. A broad zone of east dipping (20°–45°) reflections bounds the Goochland terrane on the east. These reflections may originate from deformation zones and continue to Moho depths. They appear to be correlative with similar events seen on other Appalachian lines. The pervasiveness of the zone of east dipping events on other seismic reflection lines and the continuity of the adjacent Piedmont gravity high suggest continuity of crustal features along the length of the Appalachians. A major conclusion of this study is that crustal thinning is responsible for the main components of the gravity field in Virginia, that is, the Appalachian gravity gradient and the Piedmont gravity high. The crust thins from about 52 km beneath the Appalachian mountains to about 35 km beneath Richmond, Virginia, and then rethickens by up to 10 km beneath the zone of east dipping reflections (mylonites?) east of Richmond. The I‐64 seismic data also contain a sequence of reflections at about 9–12 s, indicative of lower crustal layering; the base of this zone of reflections coincides almost exactly with the Mohorovicic discontinuity interpreted from earlier refraction work. The layering extends about 70 km west from Richmond, Virginia, and is interpreted as a lower crustal transition zone that is believed to persist across most of Virginia.

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Stratigraphy and tectonics of the Virginia–North Carolina Blue Ridge: Evolution of a late Proterozoic–early Paleozoic hinge zone

Wehr

Glover

1985

Geol Soc America Bull

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Lynn Glover

Seismic structure of the U.S. Mid‐Atlantic continental margin

Geology of the Coamo area, Puerto Rico, and its relation to the volcanic arc-trench association

Deep seismic reflection data of EDGE U.S. mid-Atlantic continental-margin experiment: Implications for Appalachian sutures and Mesozoic rifting and magmatic underplating

A geophysical study of the Earth's crust in central Virginia: Implications for Appalachian crustal structure

Stratigraphy and tectonics of the Virginia–North Carolina Blue Ridge: Evolution of a late Proterozoic–early Paleozoic hinge zone

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