Your search keyword '"Ahmad, Talat"' showing total 6 results

1. Geochemistry of meta‐sediments from Neoproterozoic Shimla and Chail Groups of Outer Lesser Himalaya: Implications for provenance, tectonic setting, and paleo‐weathering conditions.

Author

Joshi, Kumar Batuk, Ray, Soumya, Ahmad, Talat, Manavalan, Satyanarayanan, and Aradhi, Keshav Krishna

Subjects

GEOCHEMISTRY, PROVENANCE (Geology), TRANSITION metals, TRACE elements, AGE distribution, SEVERE storms, ARCHAEAN

Abstract

The depositional history of the Himalayas has been overprinted by the tectonic activities during the Himalayan Orogeny. A detailed investigation of the sedimentary units can provide crucial information regarding their depositional history and provenance. This study aims at constraining the weathering history, tectonic setting, and provenance of meta‐sediments from the Shimla and Chail Groups of Outer Lesser Himalaya. With similar major element chemistry, these meta‐sediments comprise a low‐silica group (avg. SiO2/Al2O3 <3.29). Weathering intensity parameters chemical index of alteration (CIA), plagioclase index of alteration (PIA) and index of chemical variability (ICV) range from 62 to 78 (avg. = 69.41), 70 to 96 (avg. = 85.34), and 0.45 to 1.45 (avg. = 1.01), respectively indicating moderate to severe degrees of weathering. Transition element ratios [Cr/V (1.68–5.18), Ni/Co (1.47–30.99), and V/Ni (0.87–4.61)], and trace element bivariate plots suggest a recycled, felsic to intermediate provenance that has primarily been derived from Post‐Archean sources with minor inputs from Archean units. A passive margin depositional setting with arc‐derived sources is suggested for the Chail and Shimla meta‐sediments. Rare‐earth element patterns reveal similarities between the studied metasediments with TTG gneisses and sanukitoids from the Aravalli and Bundelkhand Cratons, as well as Chaur and Jutogh granitoids. Therefore, Neoproterozoic Himalayan granitoids and Archean Aravalli‐Bundelkhand granitoids (TTGs and high‐K granitoids) could be potential sources of these meta‐sediments, as also suggested by the detrital zircon age distribution from the Beas‐Satluj‐Pabbar valleys and Shimla Group. [ABSTRACT FROM AUTHOR]

Published

2021

2. Timescales of partial melting in the Himalayan middle crust: insight from the Leo Pargil dome, northwest India.

Author

Lederer, Graham, Cottle, John, Jessup, Micah, Langille, Jackie, and Ahmad, Talat

Subjects

MELTING, GRANITE, KINEMATICS, AMPHIBOLITES, TRACE elements, MINERALOGY

Abstract

The Leo Pargil dome (LPD) in northwest India exposes an interconnected network of pre-, syn-, and post-kinematic leucogranite dikes and sills that pervasively intrude amphibolite-facies metapelites of the mid-crustal Greater Himalayan sequence. Leucogranite bodies range from thin (5-cm-wide) locally derived sills to thick (2-m-wide) crosscutting dikes extending at least 100 m. Three-dimensional exposures elucidate crosscutting relations between different phases of melt injection and crystallization. Combined laser ablation inductively coupled plasma mass spectrometry U-Th/Pb geochronology and trace element analysis on well-characterized monazite grains from nineteen representative leucogranites yields a large, internally consistent data set of approximately 700 U-Th/Pb and 400 trace element analyses. Grain-scale variations in age correlate with trace element distributions and indicate semi-continuous crystallization of monazite from 30 to 18 Ma. The youngest U-Th/Pb ages in a given sample are consistent with the outcrop-scale crosscutting relations, whereas older ages within individual samples record inheritance from partially crystallized melt and source metapelites. U-Th/Pb isotopic and trace element data are incorporated into a model of melting within the LPD that involves (1) steady-state equilibrium batch melting of compositionally homogeneous metapelitic sources; (2) pulses of increased melt mobility lasting 1-2 m.y. resulting in segregation of melt from its source and amalgamation into mixed magmas; and (3) rapid emplacement and final crystallization of leucogranite bodies. Melt systems in the LPD evolved from locally derived, in situ melt in migmatitic source rocks into a vast network of dikes and sills in the overlying non-migmatitic host rocks. [ABSTRACT FROM AUTHOR]

Published

2013

3. Isotopic constraints on the structural relationships between the Lesser Himalayan Series and the...

Author

Ahmad, Talat and Harris, Nigel

Subjects

*STRUCTURAL geology, *THRUST faults (Geology)

Abstract

Studies the isotopic constraints on the structural relationships between the Lesser Himalayan Series and High Himalayan Crystalline Series from the Garhwal Himalaya thrust system in India. Evidence for out-of-sequence thrusting between the structures; Establishment of the value of isotopic data for lithostratigraphic correlations within orogenic belts.

Published

2000

4. Current strain accumulation in the hinterland of the northwest Himalaya constrained by landscape analyses, basin-wide denudation rates, and low temperature thermochronology.

Author

Morell, Kristin D., Sandiford, Mike, Kohn, Barry, Codilean, Alexandru, Fülöp, Réka-H., and Ahmad, Talat

Subjects

*LANDSCAPES, *STRAIN rate, *CHEMICAL denudation, *THERMOCHRONOMETRY, *LOW temperatures

Abstract

Rupture associated with the 25 April 2015 M w 7.8 Gorkha (Nepal) earthquake highlighted our incomplete understanding of the structural architecture and seismic cycle processes that lead to Himalayan mountain building in Central Nepal. In this paper we investigate the style and kinematics of active mountain building in the Himalayan hinterland of Northwest India, approximately 400 km to the west of the hypocenter of the Nepal earthquake, via a combination of landscape metrics and long- (Ma) and short-term (ka) erosion rate estimates (from low temperature thermochronometry and basin-wide denudation rate estimates from 10 Be concentrations). We focus our analysis on the area straddling the PT 2 , the physiographic transition between the Lesser and High Himalaya that has yielded important insights into the nature of hinterland deformation across much of the Himalaya. Our results from Northwest India reveal a distinctive PT 2 that separates a Lesser Himalaya region with moderate relief (∼1000 m) and relatively slow erosion ( <1 mm/yr) from a High Himalaya with extreme relief (∼2500 m), steep channels, and erosion rates that approach or exceed 1 mm/yr. The close spatial similarity in relative rates of long- and short-term erosion suggests that the gradient in rock uplift rates inferred from the landscape metrics across the PT 2 has persisted in the same relative position since at least the past 1.5 Ma. We interpret these observations to suggest that strain accumulation in this hinterland region throughout at least the past 1.5 Ma has been accomplished both by crustal thickening via duplexing and overthrusting along transient emergent faults. Despite the >400 km distance between them, similar spatiotemporal patterns of erosion and deformation observed in Northwest India and Central Nepal suggest both regions experience similar styles of active strain accumulation and both are susceptible to large seismic events. [ABSTRACT FROM AUTHOR]

Published

2017

5. Monazite geochronology unravels the timing of crustal thickening in NW Himalaya.

Author

Stübner, Konstanze, Grujic, Djordje, Parrish, Randall R., Roberts, Nick M.W., Kronz, Andreas, Wooden, Joe, and Ahmad, Talat

Subjects

*MONAZITE, *GEOLOGICAL time scales, *SEISMIC anisotropy, *AMPHIBOLITES, *SEDIMENTS, *METAMORPHISM (Geology)

Abstract

Greenschist to amphibolite grade Haimanta metasediments of the NW Himalaya preserve much of the prograde metamorphic history of Eohimalayan crustal thickening, which has been erased by Oligo-/Miocene migmatization elsewhere in the Himalaya. Our zircon and monazite U/Th–Pb data unravel a multi-stage prograde metamorphic evolution. The earliest evidence of prograde Barrovian metamorphic monazite growth is ~ 41 Ma. Peak metamorphic conditions (~ 8–8.5 kbar, ~ 600–700 °C) were attained at 37–36 Ma and followed by a prolonged evolution at high temperatures with at least three distinct episodes of monazite growth, which may be related to the formation of the northern Himalayan nappes (e.g., Shikar Beh nappe, Nyimaling nappe). Rapid exhumation of the crystalline started at ~ 26 Ma and resulted in cooling through the muscovite 40 Ar/ 39 Ar closure temperature by 21.8 Ma. Although a local continuation of the South Tibetan detachment is not unambiguously identified in central Himachal Pradesh extrusion was likely facilitated by a system of several minor late Oligocene/early Miocene top-to-the-N to NE shear zones. In contrast to the crystalline of Zanskar and eastern Himachal Pradesh, extrusion was not accompanied by widespread decompression melting. [ABSTRACT FROM AUTHOR]

Published

2014

6. Empirical constraints on extrusion mechanisms from the upper margin of an exhumed high-grade orogenic core, Sutlej valley, NW India

Author

Chambers, Jennifer, Caddick, Mark, Argles, Tom, Horstwood, Matthew, Sherlock, Sarah, Harris, Nigel, Parrish, Randall, and Ahmad, Talat

Subjects

*METAMORPHISM (Geology), *MORPHOTECTONICS, *OROGENY, *MIOCENE stratigraphic geology, *EOCENE stratigraphic geology, *DEFORMATION of surfaces, *CYANITE

Abstract

Abstract: The Early–Middle Miocene exhumation of the crystalline core of the Himalaya is a relatively well-understood process compared to the preceding phase of burial and prograde metamorphism in the Eocene–Oligocene. Highly deformed rocks of the Greater Himalayan Sequence (GHS) dominate the crystalline core, and feature a strong metamorphic and structural overprint related to the younger exhumation. The Tethyan Sedimentary Series was tectonically separated from the underlying GHS during the Miocene by the South Tibetan Detachment, and records a protracted and complex history of Cenozoic deformation. Unfortunately these typically low-grade or unmetamorphosed rocks generally yield little quantitative pressure–temperature–time information to accompany this deformation history. In parts of the western Himalaya, however, the basal unit of the Tethyan Sedimentary Series (the Haimanta Group) includes pelites metamorphosed to amphibolite facies. This presents a unique opportunity to explore the tectono-thermal evolution of crystalline rocks which record the early history of the orogen. Pressure–temperature–time–deformation (P–T–t–d) paths modelled for two Haimanta Group pelitic rocks reveal three distinct stages of metamorphism: (1) prograde Barrovian metamorphism to 610–620 °C at c. 7–8 kbars, with garnet growing over an early tectonic fabric (S1); (2) initial decompression during heating to 640–660 °C at c. 6–7 kbars, with development of a pervasive crenulation cleavage (S2) and staurolite and kyanite porphyroblast growth; (3) further exhumation during cooling, with minor retrograde metamorphism and modification of the pervasive S2 fabric. Monazite growth ages constrain the timing of initial garnet growth (>34 Ma), the start of D2 and maximum burial (c. 30 Ma), and the termination of garnet growth (c. 28 Ma). Muscovite Ar/Ar ages indicate cooling through c. 300 °C at c. 13 Ma, from which we derive an initial exhumation rate of c. 1.3 mm year−1 for the Haimanta Group. The underlying GHS was exhumed at a rate of 2.2 to 3 mm year−1 during this time. The difference in exhumation rate between these two units is considered to reflect Early Miocene displacement on the intervening South Tibetan Detachment. Slower exhumation (c. 0.6 mm year−1) of both units after c. 13 Ma followed the cessation of major displacement on this structure, after which time the Haimanta Group and the GHS were exhumed as one relatively coherent tectonic block. [Copyright &y& Elsevier]

Published

2009