Assembly of the Pamirs: Age and origin of magmatic belts from the southern Tien Shan to the southern Pamirs and their relation to Tibet

Schwab, Martina; Ratschbacher, Lothar; Siebel, Wolfgang; McWilliams, Michael; Minaev, V.; Лутков, В. С.; Chen, Fokun; Stanek, Klaus; Nelson, Bruce K.; Frisch, Wolfgang; Wooden, Joseph L.

doi:10.1029/2003tc001583

Cited by 318 publications

(649 citation statements)

References 56 publications

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“…It consists of roughly E-W trending structural belts that reflect a history of successive terrane accretion. These are commonly referred to as Northern (Paleozoic subduction-accretion complex), Central (Mesozoic platform rocks), and Southern (mostly Mesozoic metasediments) Pamir [Burtman and Molnar, 1993;Schwab et al, 2004;Mechie et al, 2012]. Correlation of the terranes and the sutures separating them from their counterparts in Tibet [e.g., Yin and Harrison, 2000] and Afghanistan [Burtman and Molnar, 1993] indicates a relative northward displacement of the entire Pamir by about 300 km.…”

Section: Tectonic Settingmentioning

confidence: 99%

“…However, lower continental crustal rocks do not typically contain any significant amount of hydrated minerals [Rudnick, 1995;Rudnick and Fountain, 1995] and should therefore predominantly deform aseismically at mantle depths. In a delamination scenario for the Pamir, the southern and central Pamir's origin from accreted volcanic arcs [Schwab et al, 2004] may provide preserved fluid reservoirs in hydrated rocks that are now released as these rocks are transported to greater depth. Alternatively, concepts of shear instabilities by thermal runaway [Kelemen and Hirth, 2007;John et al, 2009] have been proposed for the generation of intermediate-depth earthquakes.…”

Section: Processes Responsible For Intermediate-depth Seismicitymentioning

confidence: 99%

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Geometry of the Pamir‐Hindu Kush intermediate‐depth earthquake zone from local seismic data

et al. 2013

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[1] We present new seismicity images based on a two-year seismic deployment in the Pamir and SW Tien Shan. A total of 9532 earthquakes were detected, located, and rigorously assessed in a multistage automatic procedure utilizing state-of-the-art picking algorithms, waveform cross-correlation, and multi-event relocation. The obtained catalog provides new information on crustal seismicity and reveals the geometry and internal structure of the Pamir-Hindu Kush intermediate-depth seismic zone with improved detail and resolution. The relocated seismicity clearly defines at least two distinct planes: one beneath the Pamir and the other beneath the Hindu Kush, separated by a gap across which strike and dip directions change abruptly. The Pamir seismic zone forms a thin (approximately 10 km width), curviplanar arc that strikes east-west and dips south at its eastern end and then progressively turns by 90°to reach a north-south strike and a due eastward dip at its southwestern termination. Pamir deep seismicity outlines several streaks at depths between 70 and 240 km, with the deepest events occurring at its southwestern end. Intermediate-depth earthquakes are clearly separated from shallow crustal seismicity, which is confined to the uppermost 20-25 km. The Hindu Kush seismic zone extends from 40 to 250 km depth and generally strikes east-west, yet bends northeast, toward the Pamir, at its eastern end. It may be divided vertically into upper and lower parts separated by a gap at approximately 150 km depth. In the upper part, events form a plane that is 15-25 km thick in cross section and dips sub-vertically north to northwest. Seismic activity is more virile in the lower part, where several distinct clusters form a complex pattern of sub-parallel planes. The observed geometry could be reconciled either with a model of two-sided subduction of Eurasian and previously underthrusted Indian continental lithosphere or by a purely Eurasian origin of both Pamir and Hindu Kush seismic zones, which necessitates a contortion and oversteepening of the latter.

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Section: Tectonic Settingmentioning

confidence: 99%

Section: Processes Responsible For Intermediate-depth Seismicitymentioning

confidence: 99%

Geometry of the Pamir‐Hindu Kush intermediate‐depth earthquake zone from local seismic data

et al. 2013

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“…In particular, the Cretaceous arc-type granitoids in the Central and Southern Pamir have been linked to equivalents in Tibet. However, the details of such correlations are still debated (e.g., Schwab et al, 2004;Robinson, 2009).…”

Section: Tectonic Settingmentioning

confidence: 99%

“…The domes cover up to 30 % of the Pamir and expose crystalline basement and metamorphic rocks (Vlasov et al, 1991;Brunel et al, 1994;Schwab et al, 2004;Robinson Schmidt et al, 2011;Stübner et al, 2013) The Kurgovat Dome of the Northern Pamir consists of high-grade metamorphosed Triassic rocks. The domes in the Central Pamir (Yazgulom, Sarez, Muskol and Shatput domes; Fig.…”

Section: Tectonic Settingmentioning

confidence: 99%

“…Situated at the western end of the India-Asia collision zone, the Pamir have experienced some of the highest deformation rates on the planet (e.g., Burtman and Molnar, 1993;Pegler and Das, 1998;Reigber et al, 2001;Ducea et al, 2003;Wheeler et al, 2005). The topography of the Pamir is dominated by a series of Oligo-Miocene domes (Hubbard et al, 1999;Ducea et al, 2003;Schwab et al, 2004;Amidon and Hynek, 2010). The timing and mechanism of dome exhumation and the distribution of neotectonic activity are a focus of research in the Pamir (e.g., Schmidt et al, 2011;Schneider et al, 2013;Sippl et al, 2013;Stübner et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Rates of river incision across the main tectonic units of the Pamir identified using optically stimulated luminescence dating of fluvial terraces

et al. 2014

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Calculated incision rates along the Panj, the main river of the Pamir, are used to investigate any influence by tectonics or climate on the architecture of the river. The depositional ages of Panj river terraces were calculated using optically stimulated luminescence (OSL) dating of terrace sand. Fluvial incision rates were generated by integrating the terrace depositional ages with accurate kinematic GPS measurements of terrace heights above the modern Panj. We investigated 16 terraces along the Panj at the western Pamir margin and one terrace from the Vakhsh River to the north of the Pamir. The results reveal brief periods of fluvial deposition over the past 26 kyr. The oldest Panj terrace depositional ages coincide with early MIS 2 and MIS 2/1 glaciations on the Pamir Plateau. Younger terrace ages have no apparent link with glacial cycles. Terraces with varying heights above the modern Panj at different localities yielded similar depositional ages. This suggests that local conditions have determined fluvial incision rates. Combining all of the terrace measurements, the average incision rate of the Panj over the last 26 kyr has been ∼5.6 mm/yr. A high mean incision rate of ∼7.3 mm/yr was calculated from terraces where the Panj has cut a steep-sided valley through the Shakhdara Dome. Significantly lower incision rates (∼2 -3 mm/yr) were calculated from terraces where the Panj flows along the southern boundaries of the Shakhdara and Yazgulom domes. At those localities, graded segments of the Panj river profile and increased valley widths are indicative of local base levels. Downstream of the Yazgulom Dome, river incision rates are generally lower (∼4 -5 mm/yr) than the Panj average. However, there is one exception where higher incision rates (∼6 mm/yr) were calculated upstream of the Darvaz Fault Zone, a major tectonic feature that forms the western boundary of the Pamir. The Vakhsh river terrace to the north of the Pamir yielded a lower incision rate (∼3 mm/yr) compared to the Panj average. Variation in incision rates along the Panj does not correspond to changes in rock type or river catchment area. Instead, incision rates appear to have been primarily influenced by river capture across the southern and central metamorphic domes of the Pamir. Wherever the Panj cuts these domes it displays a convex river profile. The combination of localized river profile convexity and changes in incision rates across the Pamir domes indicates that the dome boundaries have been active recently.

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Partially melted, mica-bearing crust in Central Tibet

2014

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Surface wave tomography shows that the central Tibetan Plateau (the Qiangtang block) is characterized by S wave speeds as slow as 3.3 km/s at depths from 20-25 km to 45-50 km and S wave radial anisotropy of at least 4% (V SH > V SV ) that is stronger in the west than the east. The depth of the Curie temperature for magnetite inferred from satellite magnetic measurements, the depth of the α-β quartz transition inferred from V P /V S ratios, and the equilibration pressures and temperatures of xenoliths erupted from the middle to deep crust indicate that the Qiangtang crust is hot, reaching 1000°C at the Moho. This inferred thermal gradient crosses the dehydration melting solidi for crustal rocks at 20-30 km depth, implying the presence or former presence of melt in the Tibetan middle to deep crust. These temperatures do not require the wholesale breakdown of mica at these depths, because F and Ti can stabilize mica to at least 1300°C. Petrology suggests, then, that the Qiangtang middle to deep crust consists of a mica-bearing residue from which melt has been extracted or is being extracted. Wave speeds calculated for mica-bearing rocks with a subhorizontal to gently dipping foliation and 2% silicate melt are a good match to the wave speeds and anisotropy observed by seismology.

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Assembly of the Pamirs: Age and origin of magmatic belts from the southern Tien Shan to the southern Pamirs and their relation to Tibet

Cited by 318 publications

References 56 publications

Geometry of the Pamir‐Hindu Kush intermediate‐depth earthquake zone from local seismic data

Geometry of the Pamir‐Hindu Kush intermediate‐depth earthquake zone from local seismic data

Rates of river incision across the main tectonic units of the Pamir identified using optically stimulated luminescence dating of fluvial terraces

Partially melted, mica-bearing crust in Central Tibet

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