Crustal Thickness Variations across the Blue Ridge Mountains, Southern Appalachians: An Alternative Procedure for Migrating Wide-Angle Reflection Data

Hawman, Robert B.

doi:10.1785/0120070027

Cited by 14 publications

(18 citation statements)

References 25 publications

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“…For a 0.5 s delay (corresponding to energy near the end of a 0.5-s-duration source wavelet), the overestimate would range from 1.5 to 4 km (Hawman, 2008). In principle, depth errors for sections derived from migration of S-waves are smaller than those derived from migration of P-waves by a factor given by the Vp/Vs ratio, because of the smaller velocities.…”

Section: Migration Of Wide-angle Reflectionsmentioning

confidence: 99%

“…Their models show a 50-kmthick crust and Moho transition zone ~5 km thick. More recent experiments using controlled blasts (Luetgert et al, 1994) and timed quarry blasts (Hawman, 1996(Hawman, , 2004(Hawman, , 2008 are discussed later herein.…”

Section: Seismic-refraction Profi Lesmentioning

confidence: 99%

“…7) were generated from wide-angle vertical-and transverse-component data using a simplifi ed procedure for migrating common-source gathers (Hawman, 2008). Shear-wave refl ections were migrated by converting P-wave velocity models to S-wave velocity using estimates of aver age crustal Vp/Vs.…”

Section: Migration Of Wide-angle Reflectionsmentioning

confidence: 99%

“…Shear-wave refl ections were migrated by converting P-wave velocity models to S-wave velocity using estimates of aver age crustal Vp/Vs. To better evaluate and increase the reliability of events used for generating the migrated images, the data were fi rst coherency filtered using a setting that eliminated 99% of the samples in the noise window immediately preceding the arrival time for the direct P wave (Hawman, 2008). This minimized the inadvertent migration of random noise, while keeping the waveforms of coherent waveforms largely intact.…”

Section: Migration Of Wide-angle Reflectionsmentioning

confidence: 99%

“…This is an update of an earlier map for the Blue Ridge Mountains (Hawman, 2008), extended to adjacent provinces and modifi ed to incorporate additional depth soundings and reinterpretations of some events within the Blue Ridge as refl ections from the uppermost mantle rather than the Moho.…”

Section: Migration Of Wide-angle Reflectionsmentioning

confidence: 99%

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Isostatic compensation for a portion of the Southern Appalachians: Evidence from a reconnaissance study using wide-angle, three-component seismic soundings

Hawman

Khalifa

Baker

2011

Geological Society of America Bulletin

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Wide-angle refl ections generated by fi ve controlled blasts and over 110 timed quarry blasts in the Southern Appalachians were used to test models for isostatic compensation of topog raphy. The profi les cross the Appa lachian gravity gradient and gravity low and sample the highest elevations within the orogen. Migration of P, SV, and SH refl ections suggests that crustal thickness varies from 35 to 39 km within the coastal plain and 37-39 km within the Carolina terrane. It increases northwestward from 40 to 45 km across the Inner Piedmont, and then thickens to 50-52 km along the southeastern fl ank of the Blue Ridge Mountains. Crustal thickness within the Blue Ridge Mountains ranges from 47 to 56 km. Receiver functions for broadband stations GOGA and MYNC show a similar pattern in crustal thickness. Assuming Airy compensation, the correlation between elevation and Moho depth suggests a range of 50-150 kg/m 3 for the density contrast between the crustal root and mantle. The greatest Moho depths are associated not with the tallest peaks, but rather with the broadest portions of the mountain chain. This observation is consistent with regional bending of the lithosphere. However, the planar basement surface suggests that the root either predates Alleghanian thrusting, and therefore is unrelated to the present topography, or formed in response to some other mechanism. Bounds on curvature of the basement surface suggest a lower bound of 30-40 km for the effective elastic thickness of the lithosphere. This is consistent with previous estimates for the southern Appalachians based on analysis of gravity data.

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Section: Migration Of Wide-angle Reflectionsmentioning

confidence: 99%

Section: Seismic-refraction Profi Lesmentioning

confidence: 99%

Section: Migration Of Wide-angle Reflectionsmentioning

confidence: 99%

Section: Migration Of Wide-angle Reflectionsmentioning

confidence: 99%

Section: Migration Of Wide-angle Reflectionsmentioning

confidence: 99%

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Isostatic compensation for a portion of the Southern Appalachians: Evidence from a reconnaissance study using wide-angle, three-component seismic soundings

Hawman

Khalifa

Baker

2011

Geological Society of America Bulletin

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Crustal velocity structure associated with the eastern Tennessee seismic zone: Vp and Vs images based upon local earthquake tomography

et al. 2014

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We present three-dimensional P and S wave velocity models for the active eastern Tennessee seismic zone (ETSZ) using arrival time data from more than 1000 local earthquakes. A nonlinear tomography method is used that involves sequential inversion for model and hypocenter parameters. We image several velocity anomalies that persist through most of the inversion volume. Some anomalies support the presence of known features such as an ancient rift zone in northern Tennessee. Other anomalies reveal the presence of basement features that can be correlated with regional gravity and magnetic anomalies. We image a narrow, NE-SW trending, steeply dipping zone of low velocities that extends to a depth of at least 24 km and is associated with the vertical projection of the prominent New York-Alabama magnetic lineament. The low-velocity zone may have an apparent dip to the SE at depths exceeding 15 km. The low-velocity zone is interpreted as a major basement fault juxtaposing Granite-Rhyolite basement to the NW from Grenville southern Appalachian basement to the SE. Relocated hypocenters align in near-vertical segments suggesting reactivation of a distributed zone of deformation associated with a major strike-slip fault. We suggest that the ETSZ represents reactivation of an ancient shear zone established during formation of the super continent Rodinia.

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Crustal and upper mantle velocity structure in the vicinity of the eastern Tennessee seismic zone based upon radial P wave transfer functions

2015

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Teleseismic transfer function analysis is used to investigate crust and upper mantle velocity structure in the vicinity of the active eastern Tennessee seismic zone (ETSZ). The ETSZ is associated with the New York-Alabama (NY-AL) magnetic lineament, a prominent aeromagnetic anomaly indicative of Grenville-age, basement structure. Radial component, P wave transfer functions for 10 short-period stations operated by the Center for Earthquake Research and Information are inverted for velocity structure. Velocity profiles are also determined for three broadband stations by converting the instrument response to that of an S-13 short-period seismometer. Distinct differences in the velocity profiles are found for stations located on either side of the NY-AL magnetic lineament; velocities west of the lineament are lower than velocities to the east of the lineament in the upper 10 km and in the depth range 30 to 50 km. A gradational Moho boundary is found beneath several stations located in the Valley and Ridge province. A Moho boundary is absent at four Valley and Ridge stations located east of the magnetic lineament and south of 35.5°N.

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Crustal Thickness Variations across the Blue Ridge Mountains, Southern Appalachians: An Alternative Procedure for Migrating Wide-Angle Reflection Data

Cited by 14 publications

References 25 publications

Isostatic compensation for a portion of the Southern Appalachians: Evidence from a reconnaissance study using wide-angle, three-component seismic soundings

Isostatic compensation for a portion of the Southern Appalachians: Evidence from a reconnaissance study using wide-angle, three-component seismic soundings

Crustal velocity structure associated with the eastern Tennessee seismic zone: Vp and Vs images based upon local earthquake tomography

Crustal and upper mantle velocity structure in the vicinity of the eastern Tennessee seismic zone based upon radial P wave transfer functions

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