Velocity modeling of a complex deep crustal structure across the Mesoproterozoic south Delhi Fold Belt, NW India, from joint interpretation of coincident seismic wide-angle and near-offset reflection data: An approach using unusual reflections in wide-angle records

Krishna, V. G.; Rao, V. Divakara

doi:10.1029/2009jb006660

Cited by 15 publications

(5 citation statements)

References 66 publications

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“…Contrarily, high-resolution refraction studies with 50-to 100-m shot spacing and high-frequency sources suggest that the wide-angle reflections from the Moho arise from short discontinuous reflectors instead of a sharp first-order discontinuity/boundary similar to vertical reflection studies (Long et al, 1994). These laterally discontinuous bright lower-crustal reflections are modeled as a lamellar structure with a stack of thin layers (1-to 5-km long and 100-to 500-m thick) of alternating high and low velocities (Krishna & Vijaya Rao, 2011;Sandmeier & Wenzel, 1986). Alternatively, such a complex lower-crustal reflectivity can be modeled by a medium of random distribution of scatterers (Gibson & Levander, 1988).…”

Section: Lower Crust and Reflection Mohomentioning

confidence: 89%

“…There are some limitations to migrate the deep crustal seismic data due to the short length of reflectors, low S/N ratio, and difficulty in deriving the appropriate velocity model (Warner, 1987). The velocity model for the Delhi fold belt region (Figure 1b), which is located just 50 km to the west of the present profile, is used as the initial velocity model for migration (Krishna & Vijaya Rao, 2011). Refraction/wide-angle reflection studies in the Son Valley Vindhyan basin revealed 4.8 and 5.1-5.3 km/s as the upper and lower Vindhyan velocities, respectively (Kaila et al, 1989).…”

Section: Data Processingmentioning

confidence: 99%

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Common Reflection Surface Stack Imaging of the Proterozoic Chambal Valley Vindhyan Basin and Its Boundary Fault in the Northwest India: Constraints on Crustal Evolution and Basin Formation

et al. 2018

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The Vindhyan basin of northwestern and central India is one of the largest undeformed Meso-Neoproterozoic basins in the world with likely potential of hydrocarbons. Crustal seismic reflection data along a 165-km long Chandli-Bundi-Kota-Kunjer profile of the Chambal Valley Vindhyan basin processed using common reflection surface stack method brought out new crustal features, which were missing in earlier images. A gently dipping structure of the basin is imaged with a maximum of 7.5-km thick Proterozoic sediments, 1.5-km thick volcanic sequence, and the granitic basement at 9.0-km depth. The Great Boundary Thrust, a NW dipping crustal-scale regional tectonic feature outcropping at Bundi, and a new NW dipping reflection band from 9-to 30-km depth, named here as the Chambal thrust, are imaged beneath Bundi-Kota segment. Subduction and collision are responsible for evolution of these thrusts implying horizontal crustal growth. Seismic images of compression on one side and extension on another side along with differences in the Moho characteristics and other constraints from geophysical data around Kota indicate the presence of a new tectonic boundary with a strong lateral discontinuity and strike-slip features. The Moho topography is delineated for the first time revealing a crustal thickness ranging from 40 to 44 km. A 9-to 12-km thick mafic underplating at the lower crust suggests an important postcollisional process indicating vertical crustal growth. Based on the images from the present reflection study, a geodynamic model of the region is suggested in a plate tectonic framework, which may apply to similar Paleoproterozoic collisional areas and associated basin formation.

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Section: Lower Crust and Reflection Mohomentioning

confidence: 89%

Section: Data Processingmentioning

confidence: 99%

Common Reflection Surface Stack Imaging of the Proterozoic Chambal Valley Vindhyan Basin and Its Boundary Fault in the Northwest India: Constraints on Crustal Evolution and Basin Formation

et al. 2018

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show abstract

“…These wide-angle reflections are successfully modeled similarly as the SE-dipping reflectors (Fig. 4) revealed in the near-vertical reflection section (Krishna and Vijaya Rao, 2011). The velocity-depth model of the region (Fig.…”

Section: Deep Crustal Seismic Studymentioning

confidence: 95%

“…The velocity model derived from refraction/wide-angle reflection data (Krishna and Vijaya Rao, 2011) is presented in Fig. 4.…”

Section: Deep Crustal Seismic Studymentioning

confidence: 99%

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Evidence for the Neoproterozoic Phulad Suture Zone and Genesis of Malani magmatism in the NW India from deep seismic images: Implications for assembly and breakup of the Rodinia

Rao

Krishna²

2013

Tectonophysics

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Aravalli and Bundelkhand Cratons

Pandey

2020

Society of Earth Scientists Series

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Velocity modeling of a complex deep crustal structure across the Mesoproterozoic south Delhi Fold Belt, NW India, from joint interpretation of coincident seismic wide-angle and near-offset reflection data: An approach using unusual reflections in wide-angle records

Cited by 15 publications

References 66 publications

Common Reflection Surface Stack Imaging of the Proterozoic Chambal Valley Vindhyan Basin and Its Boundary Fault in the Northwest India: Constraints on Crustal Evolution and Basin Formation

Common Reflection Surface Stack Imaging of the Proterozoic Chambal Valley Vindhyan Basin and Its Boundary Fault in the Northwest India: Constraints on Crustal Evolution and Basin Formation

Evidence for the Neoproterozoic Phulad Suture Zone and Genesis of Malani magmatism in the NW India from deep seismic images: Implications for assembly and breakup of the Rodinia

Aravalli and Bundelkhand Cratons

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