Contrasting granitic magmatism of the Kalba fold belt (East Kazakhstan): Evidence for Late Paleozoic post-orogenic events

Kuibida, M. L.; D’yachkov, B.A.; Владимиров, А. Г.; Крук, Н. Н.; Хромых, С. В.; Котлер, П. Д.; Руднев, С. Н.; Крук, Е. А.; Kuibida, Ya.V.; Ойцева, Т. А.

doi:10.1016/j.jseaes.2018.08.027

Cited by 21 publications

(12 citation statements)

References 136 publications

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“…In the Zharma area, the Early Carboniferous (Tournaisian–Visean) sedimentary sequences (Figure 4b) contain radiolarian‐bearing chert (Iwata et al., 1997), biogenic limestone, siliceous mudstone and turbidite (Safonova et al., 2012), and they coexist with contemporaneous supra‐subduction volcanics and volcaniclastics (Safonova et al., 2018). The Late Carboniferous–Early Permian successions (Figure 4b) begin with the Moscovian molasse conglomerate above the unconformity, followed by sandstones, siltstones and coal‐bearing clays (Khromykh et al., 2020; Kuibida et al., 2019; Safonova et al., 2012). All these data suggest that the Early Carboniferous marine sedimentary environment was already replaced by a terrestrial one in the Moscovian (Khromykh et al., 2020; Safonova et al., 2012).…”

Section: Discussionmentioning

confidence: 99%

“…In other words, the Kazakhstan microcontinent was consolidated after the formation of the Zharma‐Saur arc. The Late Carboniferous–Permian I‐ and A‐type granitoids (Kuibida et al., 2016, 2019; Liu et al., 2018; Tong et al., 2014; Zhou et al., 2008) and bimodal volcanics (Khromykh et al., 2020; Zhi et al., 2019; Zhou et al., 2006) are widely distributed across the southern Altai terrane, the Irtysh‐Zaisan suture and the Zharma‐Saur arc, and they are thought to be the products of either post‐collisional (Khromykh et al., 2020; Kuibida et al., 2016, 2019; Li et al., 2015; Liu et al., 2018; Tong et al., 2014; Zhou et al., 2008) or subduction‐related magmatism (Chen et al., 2017b, 2017c; Song, Xiao, Windley, et al., 2020; Xiao et al., 2015).…”

Section: Geological Settingmentioning

confidence: 99%

“…On the other hand, the large‐scale convergence along the Irtysh‐Zaisan suture ceased at ∼320 Ma, as indicated by a Paleozoic global plate model based on high quality paleomagnetic and comprehensive geological data (Domeier & Torsvik, 2014), followed by the sluggish convergence and strike‐slip motion along the southern margin of the Siberian continent (Buslov et al., 2004; Li et al., 2017) and the northern margin of the Kazakhstan microcontinent (Choulet et al., 2011) during the Late Carboniferous to Early Permian. Furthermore, the subduction‐related magmatism occurred at the northwestern margin of the Kazakhstan microcontinent during the Devonian–Early Carboniferous (Safonova et al., 2012, 2018), but the Late Carboniferous–Permian magmatism was generated in a post‐collisional setting (Khromykh et al., 2020; Kuibida et al., 2016, 2019), suggesting the Siberia‐Kazakhstan collision in the Late Carboniferous. Therefore, the bottleneck is when the Siberian continent docked with the Kazakhstan microcontinent of eastern Laurussia and incorporated into Laurasia/Pangea.…”

Section: Introductionmentioning

confidence: 99%

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The Serpukhovian–Bashkirian Amalgamation of Laurussia and the Siberian Continent and Implications for Assembly of Pangea

Han

Liao

et al. 2022

Tectonics

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The final assembly of Pangea is thought to be marked by the Siberia‐Laurussia amalgamation during the Late Carboniferous–Permian, but there are large uncertainties on the timing of the amalgamation in the previous paleogeographic reconstructions because there are no high‐quality Carboniferous–Permian paleomagnetic data available from the Siberian continent. The Zharma‐Saur area in the junction between the Siberia‐Laurussia amalgamation, involving the Zharma‐Saur arc on the northern margin of the Kazakhstan microcontinent, the South Chinese Altai terrane in the southern margin of the Siberian continent and the Irtysh‐Zaisan suture in between, can provide crucial geological constraints for the assembly of Pangea. In the Zharma‐Saur arc, the Tournaisian–Visean marine sequences are interbedded with thick pillow lavas, which were formed during southward subduction of the Irtysh‐Zaisan Ocean and unconformably covered by the Moscovian terrestrial bimodal volcanic associations and sedimentary successions, in which the basalts are columnar‐jointed in structure and the sandstones also contain the detritus derived from the South Chinese Altai terrane. The Serpukhovian–Bashkirian unconformity was coeval with the transition from the Tournaisian–Visean calc‐alkaline to the Moscovian–Early Permian high alkaline and bimodal volcanism. These dramatic changes in sedimentary environments, provenances and volcanism together indicate the Siberia‐Laurussia amalgamation during the Serpukhovian–Bashkirian and this event was almost simultaneous with the Laurussia‐Gondwana collision and the welding of Laurussia with the Kazakhstan microcontinent, but slightly earlier than the Laurussia‐Tarim collision. Therefore, the final assembly of Pangea could be completed in the Late Carboniferous.

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Section: Discussionmentioning

confidence: 99%

Section: Geological Settingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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The Serpukhovian–Bashkirian Amalgamation of Laurussia and the Siberian Continent and Implications for Assembly of Pangea

Han

Liao

et al. 2022

Tectonics

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“…Early Silurian stitching plutons post-date the closure timing of the Hebukesaier Ocean between the BC and Tarbagtay arcs (Yang et al, 2019;Du et al, 2019). It is widely accepted that southward subduction of the Zaysan Ocean beneath the northern West Junggar took place during the Middle Devonian to Early Carboniferous (Windley et al, 2007;Vladimirov et al, 2008Liu et al, 2018a;Kuibida et al, 2019). Thus, more evidence should be provided to support the Zaysan Ocean subduction-related model.…”

Section: Tectonic Implications 531 An Early Devonian Fore-arc Settimentioning

confidence: 99%

Detrital Zircon U‐Pb Geochronology and Provenance of the Hebukesaier Formation in the Shaerbuerti Mountains, Northern West Junggar: Implication for Devonian Subduction of the Junggar–Balkhash Ocean

Liang

Chen

et al. 2020

Acta Geologica Sinica (Eng)

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Limited Devonian magmatic record in northern West Junggar leads to contrasting models on its tectonic evolution. In this study, we conducted LA-ICP-MS U-Pb dating on detrital zircons of two sandstones from the Hebukesaier Formation in the Shaerbuerti Mountains. Detrital zircons with oscillatory zoning are characterized by high Th/U (> 0.3) and low La/Yb (< 0.15), indicating their magmatic origin. The youngest zircon ages of two samples are 402 ± 2 Ma and 406 ± 2 Ma, respectively, suggesting that the Hebukesaier Formation was deposited at the Early Devonian. Detrital zircon age patterns show single peaks (at ca. 424 Ma, n =157), which indicates that these clastics were likely proximal accumulation after short distance transportation. Provenance of the Hebukesaier Formation was the Xiemisitai and Shaerbuerti Mountains. Detrital zircon ages range from 481 Ma to 395 Ma, which indicates that there was relatively continuous Early Paleozoic magmatism in the Xiemisitai and Shaerbuerti Mountains since the Early Ordovician. Age spectrums of sampled detrital zircons are distinct from those of Lower Devonian strata either in southern West Junggar or in East Junggar, which implies for individual tectonic evolution of northern West Junggar. We favor that Lower Devonian Hebukesaier Formation was developed in a fore-arc setting due to the northward subduction of the Junggar-Balkhash Ocean.

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“…1 -четвертичные аллювиальные отложения; 2 -неоген-четвертичные базальты; 3 -аплит-пегматитовые дайки комплекса Кана (К 2 ); 4 -гранит-лейкограниты комплекса Кана (К 2 ); 5 -меловые дайки кислого и основного состава, нерасчлененные; 6 -монцогранодиориты и калиевые граниты комплекса Деока (К 2 ); 7 -позднемеловые риолиты, трахириолиты, дациты, андезиты и их туфы (формация Нячанг); 8 -верхнемеловые конгломераты, гравелиты, песчаники, алевролиты (формация Даклум); 9 -граниты комплекса Анкроет (К 1 ); 10 -кварцдиорит-гранодиорит-граниты комплекса Динькуан (К 1 ); 11 -раннемеловые дациты, риодациты, риолиты, фельзиты и их туфы, формация Дондуон (а); верхнеюрские-раннемеловые андезиты, дациты и их туфы, формация Деобаолок -Като (б); 12 -нижне-среднеюрские песчаники, алевролиты, известковистые алевролиты, переслаивание мергелей и глинистых известняков, нерасчленённые; 13 -среднетриасовые конгломераты, гравелиты, песчаники, аргиллиты, сланцы, фельзиты, риолиты и их туфы (формация Манян); 14 -метаморфизованные образования докембрийского кристаллического выступа Контум (Индосинийский микроконтинент); 15 -разломы: установленные (а) и предполагаемые (б); 16 -направление смещений; 17-элементы залегания слоистости; 18 -местоположение палеовулканических структур, в кружках: N -Нячанг, L -Лаклам, D -Дапрен. Центрально-Азиатском складчатом поясе [15,16,45] и на Восточной окраине Тихого океана [30,31]. Гранитоидные батолиты, входящие в комплекс Анкроет (альб -сеноман) представляют собой ключевую тектоно-магматическую единицу в истории геологического развития зоны Далат.…”

Section: этапы и масштабы магматизмаunclassified

Geology and Thermochronology of Cretaceous Magmatism of Southeast Vietnam

Vladimirov¹,

Phan²,

Travin³

et al. 2020

Self Cite

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Геология и термохронология мелового магматизма Юго-Восточного ВьетнамаРис. 1. Геодинамическая схема восточной окраины Азии и Инд-Евразийского коллизионного орогена [10,11,17,32], с авторскими изменениями.1 -главные тектонические нарушения; 2-4 -зоны: континентальной коллизии (2), субдукции (3), спрединга (4); 5 -генеральное направление движения плиты Изанаги (а) и направления смещения блоков под действием Индо-Евразийской коллизии (б); 6-7направления сдвиговых смещений вдоль систем разломов и сдвиговых зон: в меловое (6) и кайнозойское (7) время; 8 -пояса меловой тектоно-магматической активности, формирующие Восточно-Азиатскую глобальную сдвиговую зону. ВПП -вулканоплутонические пояса. ЦСАС -Центральный Сихотэ-Алиньский сдвиг. СРКР -система разломов Красной Реки.

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Contrasting granitic magmatism of the Kalba fold belt (East Kazakhstan): Evidence for Late Paleozoic post-orogenic events

Cited by 21 publications

References 136 publications

The Serpukhovian–Bashkirian Amalgamation of Laurussia and the Siberian Continent and Implications for Assembly of Pangea

The Serpukhovian–Bashkirian Amalgamation of Laurussia and the Siberian Continent and Implications for Assembly of Pangea

Detrital Zircon U‐Pb Geochronology and Provenance of the Hebukesaier Formation in the Shaerbuerti Mountains, Northern West Junggar: Implication for Devonian Subduction of the Junggar–Balkhash Ocean

Geology and Thermochronology of Cretaceous Magmatism of Southeast Vietnam

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