Gneiss Dome Formation in the Himalaya and southern Tibet

2019 ◽  
Vol 483 (1) ◽  
pp. 401-422 ◽  
Author(s):  
Micah J. Jessup ◽  
Jackie M. Langille ◽  
Timothy F. Diedesch ◽  
John M. Cottle
Keyword(s):  
Tibetan Plateau ◽  
Late Miocene ◽  
Shear Zones ◽  
Crustal Thickening ◽  
Southern Tibet ◽  
Gneiss Domes ◽  
Time Deformation ◽  
Temperature Time ◽  
The Himalaya ◽  
Parallel Extension

AbstractGneiss domes in the Himalaya and southern Tibet record processes of crustal thickening, metamorphism, melting, deformation and exhumation during the convergence between the Indian and Eurasian plates. We review two types of gneiss domes: North Himalayan gneiss domes (NHGD) and later domes formed by orogen-parallel extension. Located in the southern Tibetan Plateau, the NHGD are cored by granite and gneiss, and mantled by the Tethyan sedimentary sequence. The footwall of these were extruded southwards from beneath the Tibetan Plateau and subsequently warped into a domal shape. The second class of domes were formed during displacement on normal-sense shear zones and detachments that accommodated orogen-parallel extension during the Late Miocene. In some cases, formation of these domes involved an early stage of southwards-directed extrusion prior to doming. We review evidence for orogen-parallel extension to provide context for the formation of these gneiss domes. Compilations of pressure–temperature–time–deformation data and temperature–time paths indicate differences between dome types, and we accordingly propose new terminology. Type 1 domes are characterized by doming as an artefact of post-high-temperature exhumation processes in the Middle Miocene. Type 2 domes formed in response to exhumation during orogen-parallel extension in the Late Miocene that potentially post-dates south-directed extrusion.

Pressure—temperature—time ( P — T — t ) histories of erogenic belts

1987 ◽  
Vol 321 (1557) ◽  
pp. 27-45 ◽  
Keyword(s):  
Thermal Relaxation ◽  
Granite Gneiss ◽  
Crustal Thickening ◽  
Crustal Extension ◽  
Gneiss Domes ◽  
Short Time Span ◽  
Differential Uplift ◽  
Metamorphic Terranes ◽  
Short Time ◽  
Temperature Time

Thermal modelling shows that a cycle of crustal thickening and erosion reproduces many of the characteristics of medium-pressure metamorphic terranes. In contrast, the structural and metamorphic features of high-pressure terranes suggest rapid exhumation, possibly tectonically as fault-bounded blocks. Low-pressure metamorphism requires an augmented heat supply. Such terranes are characterized by granite—gneiss domes, and evidence of crustal extension, and hence may be the result of the mechanically likely orogenic sequence of early thickening followed by extension. Whether earlier isograd sequences are extended, condensed, or reset depends upon the relative rates of deformation and thermal relaxation, and when the deformation occurs relative to the thermal peak of metamorphism. Detailed determinations of relations between deformation events and metamorphism is made difficult by the contrast between continuous metamorphic evolution and short time-span deformation events. Combined microstructural and geochronological studies, together with a consideration of the distribution of isograds will give most information on complex, polymetamorphic histories, and allow distinction between regional and local features, especially those due to differential uplift.

Crustal melt granites and migmatites along the Himalaya: melt source, segregation, transport and granite emplacement mechanisms

2009 ◽  
Vol 100 (1-2) ◽  
pp. 219-233 ◽  
Author(s):  
M. P. Searle ◽  
J. M. Cottle ◽  
M. J. Streule ◽  
D. J. Waters
Keyword(s):  
Partial Melting ◽  
Shear Zone ◽  
Internal Heat ◽  
Shear Zones ◽  
Source Rocks ◽  
Crustal Thickening ◽  
Main Central Thrust ◽  
Crustal Layer ◽  
Middle Crust ◽  
The Himalaya

ABSTRACTIndia–Asia collision resulted in crustal thickening and shortening, metamorphism and partial melting along the 2200 km-long Himalayan range. In the core of the Greater Himalaya, widespread in situ partial melting in sillimanite+K-feldspar gneisses resulted in formation of migmatites and Ms+Bt+Grt+Tur±Crd±Sil leucogranites, mainly by muscovite dehydration melting. Melting occurred at shallow depths (4–6 kbar; 15–20 km depth) in the middle crust, but not in the lower crust. 87Sr/86Sr ratios of leucogranites are very high (0·74–0·79) and heterogeneous, indicating a 100 crustal protolith. Melts were sourced from fertile muscovite-bearing pelites and quartzo-feldspathic gneisses of the Neo-Proterozoic Haimanta–Cheka Formations. Melting was induced through a combination of thermal relaxation due to crustal thickening and from high internal heat production rates within the Proterozoic source rocks in the middle crust. Himalayan granites have highly radiogenic Pb isotopes and extremely high uranium concentrations. Little or no heat was derived either from the mantle or from shear heating along thrust faults. Mid-crustal melting triggered southward ductile extrusion (channel flow) of a mid-crustal layer bounded by a crustal-scale thrust fault and shear zone (Main Central Thrust; MCT) along the base, and a low-angle ductile shear zone and normal fault (South Tibetan Detachment; STD) along the top. Multi-system thermochronology (U–Pb, Sm–Nd, 40Ar–39Ar and fission track dating) show that partial melting spanned ̃24–15 Ma and triggered mid-crustal flow between the simultaneously active shear zones of the MCT and STD. Granite melting was restricted in both time (Early Miocene) and space (middle crust) along the entire length of the Himalaya. Melts were channelled up via hydraulic fracturing into sheeted sill complexes from the underthrust Indian plate source beneath southern Tibet, and intruded for up to 100 km parallel to the foliation in the host sillimanite gneisses. Crystallisation of the leucogranites was immediately followed by rapid exhumation, cooling and enhanced erosion during the Early–Middle Miocene.

Evolution of Asian monsoons and phased uplift of the Himalaya–Tibetan plateau since Late Miocene times

Nature ◽  
2001 ◽  
Vol 411 (6833) ◽  
pp. 62-66 ◽  
Author(s):  
An Zhisheng ◽  
John E. Kutzbach ◽  
Warren L. Prell ◽  
Stephen C. Porter
Keyword(s):  
Tibetan Plateau ◽  
Late Miocene ◽  
Asian Monsoons ◽  
The Himalaya

scholarly journals Vertical strain partitioning in hot Variscan crust: Syn-convergence escape of the Pyrenees in the Iberian-Armorican syntax

2017 ◽  
Vol 188 (6) ◽  
pp. 39 ◽  
Author(s):  
Bryan Cochelin ◽  
Dominique Chardon ◽  
Yoann Denèle ◽  
Charles Gumiaux ◽  
Benjamin Le Bayon
Keyword(s):  
Lower Crust ◽  
Shear Zones ◽  
Crustal Thickening ◽  
Upper Crust ◽  
Strain Partitioning ◽  
Kinematic Data ◽  
Mechanical Coupling ◽  
Gneiss Domes ◽  
Lateral Escape ◽  
Lower Crustal

A new structural map of the Paleozoic crust of the Pyrenees based on an extensive compilation and new kinematic data allows for the evaluation of the mechanical coupling between the upper and lower crust of the abnormally hot foreland of the Variscan orogen of SW Europe. We document partitioning between coeval lower crustal lateral flow and upper crustal thickening between 310 and 290 Ma under an overall dextral transpressive regime. Partitioning also involved syn-convergence transtensional gneiss domes emplacement during this period. Late orogen-normal shortening of the domes and strain localization in steep crustal-scale transpressive shear zones reflects increasing coupling between the lower crust and the upper crust. The combination of dextral transpression and eastward flow in the Pyrenees results from the shortening and lateral escape of a hot buoyant crust along the inner northern limb of the closing Cantabrian orocline at the core of the Iberian-Armorican arc between ca. 305 and 295 Ma. Delamination or thermal erosion of the lithosphere enhanced orocline closure and explains (1) the switch from crust- to mantle-derived magmatism in the Iberian-Armorican arc and (2) the abnormally hot and soft character of the Pyrenean crust that escaped the closing syntax.

Thermobarometry and geochronology of the Uvauk complex, a polymetamorphic Neoarchean and Paleoproterozoic segment of the Snowbird tectonic zone, Nunavut, Canada

2007 ◽  
Vol 44 (2) ◽  
pp. 245-266 ◽  
Author(s):  
A J Mills ◽  
R G Berman ◽  
W J Davis ◽  
S Tella ◽  
S Carr ◽  
...  
Keyword(s):  
High Pressure ◽  
Shear Zones ◽  
Granulite Facies ◽  
Crustal Thickening ◽  
High Grade ◽  
Retrograde Metamorphism ◽  
Tectonic Zone ◽  
History Of ◽  
Thermal Overprint ◽  
Temperature Time

The Uvauk complex is an ultramylonite-bounded, granulite-facies suite of anorthosite–gabbro that forms part of the Chesterfield Inlet segment of the Snowbird tectonic zone. Following initial anorthosite–gabbro magmatism at ca. 2.71 Ga and a cryptic 2.62–2.60 Ga event marked by zircon and monazite growth, the Uvauk complex experienced two high-grade tectonometamorphic events at 2.56–2.50 and 1.91–1.90 Ga. Similar to the 2.56–2.50 Ga development of other shear zones in the region, the upper-amphibolite-facies to granulite-facies, moderately high-pressure (8.4–11.0 kbar and 705–760 °C) (1 kbar = 100 MPA) M1 event is interpreted to have involved the structural emplacement of ca. 2.71 Ga Uvauk complex rocks on ca. 2.68 Ga tonalitic rocks to the south. Granulite-facies, high-pressure (11.2–14.7 kbar and 695–865 °C) M2 metamorphism, gabbroic magmatism, and mylonite development within the complex at ca. 1.9 Ga culminated with ~3.5 kbar decompression at high temperature. Clockwise pressure–temperature–time (P–T–t) paths reflect crustal thickening, thought to be related to the early accretionary history of the Trans-Hudson Orogen. A thermal overprint at ca. 1.85–1.75 Ga resulted in retrograde metamorphism (5.8–6.0 kbar and 625–695 °C) associated with post-tectonic granitoid plutonism.

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