Abstract:The Doi Inthanon and Doi Suthep metamorphic core complexes in northern Thailand are comprised of amphibolite-grade migmatitic gneisses mantled by lower-grade mylonites and metasedimentary sequences, thought to represent Cordilleran-style core complexes exhumed through the mobilization of a low-angle detachment fault. Previous studies have interpreted two metamorphic events (Late Triassic and Late Cretaceous), followed by ductile extension between the late Eocene and late Oligocene, a model which infers movemen… Show more
“…Late Cretaceous (~120 Ma) ages are reported from granites with I-type affinity outcropping into the metasedimentary sequences in the vicinity of Mandalay (Barley et al, 2003, and this study), and Eocene and Miocene magmatic ages are also recorded (Barley et al, 2003, and this study;Gardiner et al, 2016a;Mitchell et al, 2012). Within the country rocks of the Mogok Metamorphic Belt, at least two phases of post-collisional Barrovian-type regional metamorphism up to sillimanite grade have been identified through zircon and monazite U-Pb geochronology: one pre-to Mid Palaeogene, and one Eocene-Oligocene (Barley et al, 2003;Searle et al, 2017;Searle et al, 2007), this latter age similar to that of Doi Inthanon in northern Thailand (Dunning et al, 1995;Gardiner et al, 2016b). Localized partial melting of the country rock also produced leucogranitic melts, with a tourmaline and garnet Himalayan-type…”
Section: Neo-tethyan Magmatic Beltssupporting
confidence: 66%
“…Inthanon Zone, reflecting minor magmatism likely related to the era of Neo-Tethys ( Figure 4) (Dunning et al, 1995;Gardiner et al, 2016b).…”
The Tethys margin in central and eastern Asia is comprised of continental terranes separated by suture zones, some of which remain cryptic. Determining the crustal architecture, and therefore the geological history, of the Eastern Tethyan margin remains challenging. Sited in the heart of this region, Myanmar is a highly prospective but poorly explored minerals jurisdiction. A better understanding of Myanmar's mineralization can only be realized through a better understanding of its tectonic history, itself reflected in at least four major magmatic belts. The Eastern and the Main Range Provinces are associated with the Late Permian to Early Triassic closure of Palaeo-Tethys. The Mogok-Mandalay-Mergui Belt and Wuntho-Popa Arc are a response to the Eocene closure of Neo-Tethys. However, magmatic ages outside these two orogenic events are also recorded. We present new zircon U-Pb, Lu-Hf and O isotope data from magmatic rocks across Myanmar, which we append to the existing dataset to isotopically characterize Myanmar's magmatic belts. Eastern Province Permian I-type magmatism has evolved ï„Hf (-10.9 to-6.4), while Main Range Province Triassic S-type magmatism also records evolved ï„Hf (-13.5 to-8.8). The Mogok-Mandalay-Mergui Belt is here divided into the Tin Province and the Mogok Metamorphic Belt. The Tin Province hosts ca. 77-50 Ma magmatism with evolved ï„Hf (-1.2 to-15.2), and ï€ 18 O of 5.6-8.3 â°. The Mogok Metamorphic Belt exhibits a more complex magmatic and metamorphic history, and granitoids record Jurassic, Late Cretaceous, and Eocene to Miocene phases of magmatism, all of which exhibit evolved ï„Hf values between-4.6 and-17.6, and ï€ 18 O between 6.3 and
“…Late Cretaceous (~120 Ma) ages are reported from granites with I-type affinity outcropping into the metasedimentary sequences in the vicinity of Mandalay (Barley et al, 2003, and this study), and Eocene and Miocene magmatic ages are also recorded (Barley et al, 2003, and this study;Gardiner et al, 2016a;Mitchell et al, 2012). Within the country rocks of the Mogok Metamorphic Belt, at least two phases of post-collisional Barrovian-type regional metamorphism up to sillimanite grade have been identified through zircon and monazite U-Pb geochronology: one pre-to Mid Palaeogene, and one Eocene-Oligocene (Barley et al, 2003;Searle et al, 2017;Searle et al, 2007), this latter age similar to that of Doi Inthanon in northern Thailand (Dunning et al, 1995;Gardiner et al, 2016b). Localized partial melting of the country rock also produced leucogranitic melts, with a tourmaline and garnet Himalayan-type…”
Section: Neo-tethyan Magmatic Beltssupporting
confidence: 66%
“…Inthanon Zone, reflecting minor magmatism likely related to the era of Neo-Tethys ( Figure 4) (Dunning et al, 1995;Gardiner et al, 2016b).…”
The Tethys margin in central and eastern Asia is comprised of continental terranes separated by suture zones, some of which remain cryptic. Determining the crustal architecture, and therefore the geological history, of the Eastern Tethyan margin remains challenging. Sited in the heart of this region, Myanmar is a highly prospective but poorly explored minerals jurisdiction. A better understanding of Myanmar's mineralization can only be realized through a better understanding of its tectonic history, itself reflected in at least four major magmatic belts. The Eastern and the Main Range Provinces are associated with the Late Permian to Early Triassic closure of Palaeo-Tethys. The Mogok-Mandalay-Mergui Belt and Wuntho-Popa Arc are a response to the Eocene closure of Neo-Tethys. However, magmatic ages outside these two orogenic events are also recorded. We present new zircon U-Pb, Lu-Hf and O isotope data from magmatic rocks across Myanmar, which we append to the existing dataset to isotopically characterize Myanmar's magmatic belts. Eastern Province Permian I-type magmatism has evolved ï„Hf (-10.9 to-6.4), while Main Range Province Triassic S-type magmatism also records evolved ï„Hf (-13.5 to-8.8). The Mogok-Mandalay-Mergui Belt is here divided into the Tin Province and the Mogok Metamorphic Belt. The Tin Province hosts ca. 77-50 Ma magmatism with evolved ï„Hf (-1.2 to-15.2), and ï€ 18 O of 5.6-8.3 â°. The Mogok Metamorphic Belt exhibits a more complex magmatic and metamorphic history, and granitoids record Jurassic, Late Cretaceous, and Eocene to Miocene phases of magmatism, all of which exhibit evolved ï„Hf values between-4.6 and-17.6, and ï€ 18 O between 6.3 and
“…2 and 6) is located in NW Thailand and experienced a complex polyphase deformation. Two major episodes of metamorphism postdate the Indosinian Orogeny viz., 1) a thermal event associated with magmatic emplacement from ~84 Ma to 72 Ma (Late Cretaceous), followed by, 2) prograde metamorphism during Eocene to Oligocene crustal thickening (Dunning et al, 1995;Gardiner et al, 2016). The final exhumation of the dome occurred in the Miocene via a low angle extensional detachment (Gardiner et al, 2016).…”
Section: Metamorphic Complexes Of West Sundalandmentioning
confidence: 99%
“…The ensuing crustal thickening was accompanied or followed by the formation of a number of metamorphic domes, such as Stong, Khanom, Khlong Marui, Ranong, Klaeng, Khabila, Doi Inthanon, and Mogok/shan scarp, which are often attributed to extensional detachments (or large normal faults) and major strike-slip displacements (Figs. 1b and 2) (e.g., Bertrand et al, 1999;Gardiner et al, 2016;Macdonald et al, 2010;Watkinson et al, 2011;Zhang et al, 2012a).…”
“…Some small basins are associated with significant recent earthquakes.Fig. 1Regional map of Central and Northern Thailand, showing the locations of major Cenozoic faults and sedimentary basins with moment tensor analyses of recent earthquakes (modified from Gardiner et al., 2016; Morley et al., 2011). …”
The Mae Suai Basin, an intermountain basin in northern Thailand, became an area of interest in 2014 following the M6.1 earthquake that reactivated the ENE-WSW trending Mae Loa Fault. This fault is associated with the Cenozoic rifting. Terrestrial gravity modelling is a suitable method to visualize subsurface geometry and understand its structural control related to the recent earthquakes. Six hundred twenty-seven terrestrial gravity stations with a spacing of âŒ500 m were collected; standard gravity correction methods were applied with a density reduction of 2.67 g/cm
3
to produce the residual Complete Bouguer anomaly (CBA). The residual CBA map reveals a NNE-SSW striking basin, showing gravity lows are located within the basin. The gravity highs cover regions of Triassic granite intrusions to the west and Silurian-Devonian metasedimentary and Carboniferous sedimentary basements to the east. Structural edge detections and basin depth estimates indicate the main fault lineaments lie ENE-SWS and NNE-SSW striking along the eastern and northern margins respectively. These faults may act as splay faults of the active sinistral Mae Loa fault. The gravity models suggest that the Mae Suai Basin is an asymmetrical half-graben with a maximum depth of âŒ770 m and a range of basin sediments from 1.9 to 2.3 g/cm
3
. The depocentre is located near the eastern boundary faults. The structural patterns present the rifting has formed within an extensional transfer zone that relates to a releasing bend fault in NNE-SSW trend, linked by the sinistral Mae Loa Fault in NE-SW trend. The E-W maximum of extension in the transfer zone is formed under the activation of the major Cenozoic strike-slip faults in Northern Thailand.
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