连接源与汇:中亚古近系同构造地层的沉积时间

IF 4.8 1区 地球科学 Q1 GEOLOGY Geology Pub Date : 2023-11-01 DOI:10.1130/g51382.1
Feng Cheng, Andrew V. Zuza, Marc Jolivet, Andreas Mulch, Niels Meijer, Zhaojie Guo
{"title":"连接源与汇:中亚古近系同构造地层的沉积时间","authors":"Feng Cheng, Andrew V. Zuza, Marc Jolivet, Andreas Mulch, Niels Meijer, Zhaojie Guo","doi":"10.1130/g51382.1","DOIUrl":null,"url":null,"abstract":"Determining the age of siliciclastic continental sequences in the absence of comprehensive biostratigraphy or radiometric dating of geological markers (e.g., volcanic layers) is inherently challenging. This issue is well exemplified in the current debate on the age of Cenozoic terrestrial strata in Central Asia, where competing age models constrained by non-unique paleomagnetic correlations are interpreted to reflect the growth of the Tibetan Plateau and its impact on Central Asian climate change. Here we present a new approach to evaluate competing age models by comparing the onset of rapid basement exhumation constrained by low-temperature thermochronology in the sediment source region with the initiation of growth strata in the adjacent sedimentary sink. We first validate this method in regions with well-constrained age models and subsequently apply this approach to the Tarim and Qaidam Basins in the northern Tibetan Plateau. The results of this analysis show that syntectonic sedimentation had already initiated during the Paleocene–Eocene and was followed by intensified Oligocene–Miocene mountain building along the northern margin of the plateau. Based on this refined Paleogene tectonic history, we further arrive at a temporal correlation between Paleogene tectonism in Northern Tibet and the retreat of the Proto-Paratethys Sea, a major water body that extended across Eurasia and was closely associated with climatic and biodiversity changes. We thus highlight the previously underestimated role tectonics in Northern Tibet had in the evolution and demise of the Proto-Paratethys Sea during the Paleogene.Because correlation of paleomagnetic data from continental basins to the Geomagnetic Polarity Time Scale (Ogg, 2020) is commonly non-unique, magnetostratigraphy alone can lead to dramatically different age models for continental siliciclastic sequences in the absence of fossils or radiometrically datable volcanic ash layers (Lowe, 2011). This inevitably leads to contrasting models for the timing, rates, and duration of tectonic and paleoclimatic processes. This fundamental challenge is well exemplified in Cenozoic terrestrial strata in Central Asia (Figs. 1A–1E), where competing age models have strongly diverging implications for the growth of the Tibetan Plateau (Ji et al., 2017; Staisch et al., 2020; Wang et al., 2022) and its association with Asia paleo-environments including the retreat of the Proto-Paratethys Sea, a major water body that covered large surfaces of Eurasia during the Paleogene (Bosboom et al., 2017; Sun and Liu, 2006; Zheng et al., 2015).The two largest terrestrial basins in the Cenozoic Tibetan orogen are the Tarim and Qaidam Basins, which contain critical archives of mountain building and paleoclimate (Fig. 1B). The growth strata and thick-bedded conglomerates in the Lulehe Formation, the basal stratigraphic unit of Cenozoic strata in the Qaidam Basin (Fig. 1D), are interpreted as synorogenic sediments that record the initiation of mountain building in Northern Tibet in response to the ca. 60 Ma India-Asia collision (Ding et al., 2022; Yin et al., 2008). However, due to a lack of directly datable geologic markers and the scarcity of vertebrate fossils, two strongly contrasting age models, with a basal age of either ca. 50 Ma (Ji et al., 2017) or ca. 30 Ma (Wang et al., 2022), have been proposed for the depositional age of the Lulehe Formation, resulting in competing models for the lateral growth history of the Tibetan Plateau (Staisch et al., 2020; Wang et al., 2022; Yin et al., 2008). A similar debate centers around the depositional age of Cenozoic strata in the Tarim Basin, where some have proposed a Pliocene age for the Artux Formation (Sun and Liu, 2006) but others have assigned ages of ca. 27–15 Ma for the same unit (Zheng et al., 2015) (Fig. 1E). This differing age assignment on the eolian- and gypsum-bearing Artux Formation has led to a fundamental debate about the timing of aridification in Central Asia (Licht et al., 2016; Liu et al., 2014; Sun and Liu, 2006). In addition, knowledge about the exact timing of deposition of Lulehe Formation affects interpretations on how the Proto-Paratethys Sea retreated permanently from Central Asia (Bosboom et al., 2017; Ma et al., 2022) (Fig. 1B) and in turn impacted the regional climate and biodiversity (Barbolini et al., 2020; Meijer et al., 2019). The latter regression was attributed to the combined effect of eustatic fluctuations and far-field tectonics in response to the India-Asia collision (Bosboom et al., 2017; Burtman and Molnar, 1993; Dupont-Nivet et al., 2007; Kaya et al., 2019). However, given strikingly different interpretations depending on the age model for the deposition of syntectonic strata in the Qaidam Basin, it remains elusive whether Paleogene tectonism along Northern Tibet impacted regression in the areal extent of the Proto-Paratethys Sea.Here we present a simple yet novel approach to assessing age models in tephra- and fossil-poor strata by linking source to sink of such sediments and examining the temporal relationship between rapid basement exhumation and syntectonic sedimentation. Applying this approach to the Tarim and Qaidam Basins, we constrain the depositional age of Paleogene syntectonic strata in both basins and explore the correlation between Paleogene tectonism in Northern Tibet with the regression of the Proto-Paratethys Sea.Magnitudes and rates of exhumation determined by low-temperature thermochronology (LTT) and growth-strata deposition provide constraints on the timing of range exhumation in and around syntectonic basins that can be interpreted to reflect major phases of fault activity. The onset timing of growth strata in the immediate vicinity of a basin-bounding fault should largely coincide with the timing of intensified exhumation linked to fault activity (Figs. 2A and 2B). Competing age models for the associated stratigraphic units can be evaluated by comparing the onset of rapid exhumation and correlative faulting revealed by LTT with the proposed age of associated growth strata defined by magnetostratigraphic correlation (Figs. 2A–2D). To validate this approach, we investigate fault activity in the Zagros fold-and-thrust belt (hereafter Zagros Mountains) in Iran and the Ruby Mountains metamorphic core complex (hereafter Ruby Mountains) in western North America (Figs. S1 and S2 in the Supplemental Material1), where the depositional ages of the syntectonic strata are well established by radiometric ages (Figs. 2E–2J). We then apply this approach to the Tarim and Qaidam Basins to evaluate the debated magnetostratigraphic ages of Paleogene syntectonic strata. By integrating these newly constrained Paleogene tectonism data from the Qaidam Basin with published LTT records (He et al., 2018), we explore the role of intra-plate deformation in driving the Proto-Paratethys Sea incursions. Geological background and statistical analyses of the Paleogene tectonism in Northern Tibet are given in Texts S1 and S2 in the Supplemental Material.In the Zagros Mountains (Figs. 2E–2G), apatite (U-Th)/He (AHe) data from the hanging wall of the Kirkuk fault record rapid reverse-faulting exhumation at ca. 8–7 Ma (Koshnaw et al., 2020b), which is consistent with the initiation of growth strata in the footwall of the Kirkuk fault at ca. 8.0 Ma (Koshnaw et al., 2017, 2020a). In the Ruby Mountains (Figs. 2H–2J), apatite fission-track (AFT) and AHe ages from the footwall of the Ruby detachment show evidence of rapid normal-faulting exhumation at 17–15 Ma (Colgan et al., 2010), coinciding with the initiation of growth strata in the hanging wall of the detachment at ca. 16 Ma (Lund Snee et al., 2016; Satarugsa and Johnson, 2000). These consistencies between the rapid exhumation and basement cooling in the source area and the initiation of growth strata in the associated sedimentary sink lend strong support to the proposed age model of the late Cenozoic strata in the Zagros and Ruby Mountains, allowing us to apply this approach to debated stratigraphic age models in Central Asia.In the northwestern Qaidam Basin, AFT data from the basement rocks in the hanging wall of fault BF1 show rapid exhumation at 50–30 Ma and 30–10 Ma (Fig. 3A). These time intervals are widely interpreted as evidence for a two-stage rock uplift of the Altyn Tagh Range (Jolivet et al., 2001; Zhang et al., 2012). As shown on section QB1 (Fig. 3A), two sequences of growth structures occur in the footwall of fault BF1 that are consistent with pulsed exhumation of the basement (Cheng et al., 2021). Following age model Q1 (Ji et al., 2017), the growth strata indicate rock uplift and basement exhumation during the Paleocene–Eocene and Oligocene–Miocene, respectively. This is consistent with the exhumation history of the Altyn Tagh basement revealed by LTT. However, following age model Q2 (Wang et al., 2022), the growth strata indicate pulsed rock uplift at >25.5–23.5 Ma and 16.5 to <6.3 Ma, separated by tectonic quiescence from 23.5 Ma to 16.5 Ma. This second scenario contradicts the Miocene exhumation of the Altyn Tagh basement indicated by LTT data (Jolivet et al., 2001; Zhang et al., 2012).In the southern Qaidam Basin, AFT and AHe data from the basement on the hanging wall of fault BF2 (Fig. 3B) show rapid exhumation at ca. 35–25 Ma, indicating rapid exhumation of the Eastern Kunlun Range from the latest Eocene to Oligocene (Clark et al., 2010; Li et al., 2021). Growth strata (section QB2, Fig. 3B) are developed in the footwall of fault BF2 (Cheng et al., 2021), suggesting a corresponding rock uplift and exhumation of the Eastern Kunlun Range. Following age model Q1, the occurrence of the growth strata indicates rapid rock uplift and exhumation of the Eastern Kunlun basement from 35.5 to <8.1 Ma, consistent with the exhumation history of the Eastern Kunlun basement revealed by LTT. However, following age model Q2, the resulting age of the growth strata requires tectonic quiescence from >25.5 Ma to 16.5 Ma with subsequent rapid rock uplift from 16.5 to <6.3 Ma. This second scenario contradicts the recognized latest Eocene–Oligocene rapid exhumation of the Eastern Kunlun basement.In the southwestern Tarim Basin (section TB1, Fig. 3C), AFT data from the hanging wall of fault BF3 reveal rapid exhumation at 24–12 Ma and 12–6 Ma, which are interpreted as evidence of two-stage rock uplift of the Western Kunlun Range (Li et al., 2019). Corresponding growth structures are observed on the footwall of fault BF3 (Wang and Wang, 2016) (Fig. 3C). Following age model T1 (Sun and Liu, 2006), the growth strata indicate a prolonged tectonic quiescence period from 65.5 Ma to 5.2 Ma, with rapid rock uplift of the basement occurring during the Pliocene (>5.2 Ma to <2.6 Ma). This contradicts the proposed late Oligocene to Miocene rapid exhumation of the Western Kunlun Range based on LTT data. However, following age model T2 (Zheng et al., 2015), the growth strata suggest rapid faulting initiation along fault BF3 at ca. 22.6 Ma, consistent with the LTT record. Moreover, in section TB2 (Fig. 3D), AFT data from the hanging wall of fault BF4 show rapid exhumation and rock uplift of the Western Kunlun Range at 15–5 Ma (Cao et al., 2015). Growth strata are well preserved in the footwall of fault BF4. Following age model T1 (Sun and Liu, 2006), the pre-growth strata indicate prolonged tectonic quiescence from 65.5 Ma to 2.6 Ma while the growth strata suggest the onset of rapid rock uplift of the Western Kunlun Range at ca. 2.6 Ma (Fig. 3D). This scenario contradicts the Miocene to Pliocene rapid exhumation of the Western Kunlun Range derived from LTT data (Cao et al., 2015). However, following age model T2, the growth strata indicate a ca. 15 Ma initiation of rapid faulting, consistent with the exhumation history of the Western Kunlun basement based on LTT.The inconsistency between the LTT data in exhuming source regions and the age of growth-strata relationships in the adjacent sedimentary basins reveals that both “young” age models (Q2 and T1) for Cenozoic strata in the Qaidam and Tarim Basins, while magnetostratigraphically reasonable, are in conflict with the exhumation history of surrounding basement units. Our analysis hence indicates that the timing of syntectonic sedimentation is in very good agreement with age models Q1 and T2. Sedimentation initiated during the Paleocene–Eocene and was followed by intensified Oligocene–Miocene mountain building along the northern Tibetan Plateau margin. This episodic mountain building along the northern margin of the Tibetan Plateau highlights key features of out-of-sequence intra-plate deformation promoted by the post-collisional convergence.Because Paleogene marine incursions in the Tarim Basin do not simply align with eustatic sea-level changes (Figs. 4A–4C), recent studies have suggested a dominant role of tectonic loading and basin filling associated with the growth of the Pamir salient in the Proto-Paratethys Sea evolution (Kaya et al., 2019). However, Paleogene marine records were recently discovered farther east in the Qaidam Basin (Ma et al., 2022) indicating that the Proto-Paratethys Sea extended into Northern Tibet, which would have been located closer to the Tarim Basin, given the 300–500 km left-lateral offset along the Altyn Tagh fault since the Eocene (Cheng et al., 2016) (Texts S3 and S4; Fig. S4). As a result, Paleogene intracontinental deformation and associated modification in surface elevations along the northern Tibetan Plateau margin could have played a crucial role in driving the Proto-Paratethys Sea retreat in addition to deformation in the Pamir (Kaya et al., 2019). However, this hypothesis remains ambiguous due to the limited LTT data in Northern Tibet (Jepson et al., 2021) and the competing age models of syntectonic strata in the Qaidam Basin.Here we combine the newly constrained depositional age data from the Qaidam Basin with published LTT data sets, which together reflect Paleogene tectonic activity in Northern Tibet. We observe a consistent temporal correlation between tectonic activity and Proto-Paratethys Sea incursions (Figs. 4A–4D). Specifically, periods of tectonic quiescence in Northern Tibet at 57–56 Ma, 48–41 Ma, and 39–36 Ma correspond to the timing of the first, second, and third incursions of the Proto-Paratethys Sea, while peaks in tectonic activity at 56–48 Ma and 41–39 Ma coincide with the first, second, and third regressions (Fig. 4D). We propose that renewed acceleration of deformation in Northern Tibet and associated surface-elevation change promoted the intermittent retreat of the Proto-Paratethys Sea, while intervening deceleration of tectonic deformation facilitated Proto-Paratethys Sea incursions.The temporal coincidence between tectonism in Northern Tibet and Proto-Paratethys Sea regression highlights the previously underestimated role of tectonics in Northern Tibet in the retreat of the vast marine domain through uplift and basin infilling, which together with the northward indentation of the Pamir salient as well as the global sea-level fall during the Eocene-Oligocene transition (Kaya et al., 2019), led to the demise of the Proto-Paratethys Sea in Central Asia.This work was supported by the National Natural Science Foundation of China (U22B6002, 41888101, 41930213) and the Alexander von Humboldt Foundation. We thank editor Robert Holdsworth, Devon Orme, Ryan Leary, and an anonymous reviewer for constructive feedback that improved the manuscript.","PeriodicalId":12642,"journal":{"name":"Geology","volume":"40 51","pages":""},"PeriodicalIF":4.8000,"publicationDate":"2023-11-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Linking source and sink: The timing of deposition of Paleogene syntectonic strata in Central Asia\",\"authors\":\"Feng Cheng, Andrew V. Zuza, Marc Jolivet, Andreas Mulch, Niels Meijer, Zhaojie Guo\",\"doi\":\"10.1130/g51382.1\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Determining the age of siliciclastic continental sequences in the absence of comprehensive biostratigraphy or radiometric dating of geological markers (e.g., volcanic layers) is inherently challenging. This issue is well exemplified in the current debate on the age of Cenozoic terrestrial strata in Central Asia, where competing age models constrained by non-unique paleomagnetic correlations are interpreted to reflect the growth of the Tibetan Plateau and its impact on Central Asian climate change. Here we present a new approach to evaluate competing age models by comparing the onset of rapid basement exhumation constrained by low-temperature thermochronology in the sediment source region with the initiation of growth strata in the adjacent sedimentary sink. We first validate this method in regions with well-constrained age models and subsequently apply this approach to the Tarim and Qaidam Basins in the northern Tibetan Plateau. The results of this analysis show that syntectonic sedimentation had already initiated during the Paleocene–Eocene and was followed by intensified Oligocene–Miocene mountain building along the northern margin of the plateau. Based on this refined Paleogene tectonic history, we further arrive at a temporal correlation between Paleogene tectonism in Northern Tibet and the retreat of the Proto-Paratethys Sea, a major water body that extended across Eurasia and was closely associated with climatic and biodiversity changes. We thus highlight the previously underestimated role tectonics in Northern Tibet had in the evolution and demise of the Proto-Paratethys Sea during the Paleogene.Because correlation of paleomagnetic data from continental basins to the Geomagnetic Polarity Time Scale (Ogg, 2020) is commonly non-unique, magnetostratigraphy alone can lead to dramatically different age models for continental siliciclastic sequences in the absence of fossils or radiometrically datable volcanic ash layers (Lowe, 2011). This inevitably leads to contrasting models for the timing, rates, and duration of tectonic and paleoclimatic processes. This fundamental challenge is well exemplified in Cenozoic terrestrial strata in Central Asia (Figs. 1A–1E), where competing age models have strongly diverging implications for the growth of the Tibetan Plateau (Ji et al., 2017; Staisch et al., 2020; Wang et al., 2022) and its association with Asia paleo-environments including the retreat of the Proto-Paratethys Sea, a major water body that covered large surfaces of Eurasia during the Paleogene (Bosboom et al., 2017; Sun and Liu, 2006; Zheng et al., 2015).The two largest terrestrial basins in the Cenozoic Tibetan orogen are the Tarim and Qaidam Basins, which contain critical archives of mountain building and paleoclimate (Fig. 1B). The growth strata and thick-bedded conglomerates in the Lulehe Formation, the basal stratigraphic unit of Cenozoic strata in the Qaidam Basin (Fig. 1D), are interpreted as synorogenic sediments that record the initiation of mountain building in Northern Tibet in response to the ca. 60 Ma India-Asia collision (Ding et al., 2022; Yin et al., 2008). However, due to a lack of directly datable geologic markers and the scarcity of vertebrate fossils, two strongly contrasting age models, with a basal age of either ca. 50 Ma (Ji et al., 2017) or ca. 30 Ma (Wang et al., 2022), have been proposed for the depositional age of the Lulehe Formation, resulting in competing models for the lateral growth history of the Tibetan Plateau (Staisch et al., 2020; Wang et al., 2022; Yin et al., 2008). A similar debate centers around the depositional age of Cenozoic strata in the Tarim Basin, where some have proposed a Pliocene age for the Artux Formation (Sun and Liu, 2006) but others have assigned ages of ca. 27–15 Ma for the same unit (Zheng et al., 2015) (Fig. 1E). This differing age assignment on the eolian- and gypsum-bearing Artux Formation has led to a fundamental debate about the timing of aridification in Central Asia (Licht et al., 2016; Liu et al., 2014; Sun and Liu, 2006). In addition, knowledge about the exact timing of deposition of Lulehe Formation affects interpretations on how the Proto-Paratethys Sea retreated permanently from Central Asia (Bosboom et al., 2017; Ma et al., 2022) (Fig. 1B) and in turn impacted the regional climate and biodiversity (Barbolini et al., 2020; Meijer et al., 2019). The latter regression was attributed to the combined effect of eustatic fluctuations and far-field tectonics in response to the India-Asia collision (Bosboom et al., 2017; Burtman and Molnar, 1993; Dupont-Nivet et al., 2007; Kaya et al., 2019). However, given strikingly different interpretations depending on the age model for the deposition of syntectonic strata in the Qaidam Basin, it remains elusive whether Paleogene tectonism along Northern Tibet impacted regression in the areal extent of the Proto-Paratethys Sea.Here we present a simple yet novel approach to assessing age models in tephra- and fossil-poor strata by linking source to sink of such sediments and examining the temporal relationship between rapid basement exhumation and syntectonic sedimentation. Applying this approach to the Tarim and Qaidam Basins, we constrain the depositional age of Paleogene syntectonic strata in both basins and explore the correlation between Paleogene tectonism in Northern Tibet with the regression of the Proto-Paratethys Sea.Magnitudes and rates of exhumation determined by low-temperature thermochronology (LTT) and growth-strata deposition provide constraints on the timing of range exhumation in and around syntectonic basins that can be interpreted to reflect major phases of fault activity. The onset timing of growth strata in the immediate vicinity of a basin-bounding fault should largely coincide with the timing of intensified exhumation linked to fault activity (Figs. 2A and 2B). Competing age models for the associated stratigraphic units can be evaluated by comparing the onset of rapid exhumation and correlative faulting revealed by LTT with the proposed age of associated growth strata defined by magnetostratigraphic correlation (Figs. 2A–2D). To validate this approach, we investigate fault activity in the Zagros fold-and-thrust belt (hereafter Zagros Mountains) in Iran and the Ruby Mountains metamorphic core complex (hereafter Ruby Mountains) in western North America (Figs. S1 and S2 in the Supplemental Material1), where the depositional ages of the syntectonic strata are well established by radiometric ages (Figs. 2E–2J). We then apply this approach to the Tarim and Qaidam Basins to evaluate the debated magnetostratigraphic ages of Paleogene syntectonic strata. By integrating these newly constrained Paleogene tectonism data from the Qaidam Basin with published LTT records (He et al., 2018), we explore the role of intra-plate deformation in driving the Proto-Paratethys Sea incursions. Geological background and statistical analyses of the Paleogene tectonism in Northern Tibet are given in Texts S1 and S2 in the Supplemental Material.In the Zagros Mountains (Figs. 2E–2G), apatite (U-Th)/He (AHe) data from the hanging wall of the Kirkuk fault record rapid reverse-faulting exhumation at ca. 8–7 Ma (Koshnaw et al., 2020b), which is consistent with the initiation of growth strata in the footwall of the Kirkuk fault at ca. 8.0 Ma (Koshnaw et al., 2017, 2020a). In the Ruby Mountains (Figs. 2H–2J), apatite fission-track (AFT) and AHe ages from the footwall of the Ruby detachment show evidence of rapid normal-faulting exhumation at 17–15 Ma (Colgan et al., 2010), coinciding with the initiation of growth strata in the hanging wall of the detachment at ca. 16 Ma (Lund Snee et al., 2016; Satarugsa and Johnson, 2000). These consistencies between the rapid exhumation and basement cooling in the source area and the initiation of growth strata in the associated sedimentary sink lend strong support to the proposed age model of the late Cenozoic strata in the Zagros and Ruby Mountains, allowing us to apply this approach to debated stratigraphic age models in Central Asia.In the northwestern Qaidam Basin, AFT data from the basement rocks in the hanging wall of fault BF1 show rapid exhumation at 50–30 Ma and 30–10 Ma (Fig. 3A). These time intervals are widely interpreted as evidence for a two-stage rock uplift of the Altyn Tagh Range (Jolivet et al., 2001; Zhang et al., 2012). As shown on section QB1 (Fig. 3A), two sequences of growth structures occur in the footwall of fault BF1 that are consistent with pulsed exhumation of the basement (Cheng et al., 2021). Following age model Q1 (Ji et al., 2017), the growth strata indicate rock uplift and basement exhumation during the Paleocene–Eocene and Oligocene–Miocene, respectively. This is consistent with the exhumation history of the Altyn Tagh basement revealed by LTT. However, following age model Q2 (Wang et al., 2022), the growth strata indicate pulsed rock uplift at >25.5–23.5 Ma and 16.5 to <6.3 Ma, separated by tectonic quiescence from 23.5 Ma to 16.5 Ma. This second scenario contradicts the Miocene exhumation of the Altyn Tagh basement indicated by LTT data (Jolivet et al., 2001; Zhang et al., 2012).In the southern Qaidam Basin, AFT and AHe data from the basement on the hanging wall of fault BF2 (Fig. 3B) show rapid exhumation at ca. 35–25 Ma, indicating rapid exhumation of the Eastern Kunlun Range from the latest Eocene to Oligocene (Clark et al., 2010; Li et al., 2021). Growth strata (section QB2, Fig. 3B) are developed in the footwall of fault BF2 (Cheng et al., 2021), suggesting a corresponding rock uplift and exhumation of the Eastern Kunlun Range. Following age model Q1, the occurrence of the growth strata indicates rapid rock uplift and exhumation of the Eastern Kunlun basement from 35.5 to <8.1 Ma, consistent with the exhumation history of the Eastern Kunlun basement revealed by LTT. However, following age model Q2, the resulting age of the growth strata requires tectonic quiescence from >25.5 Ma to 16.5 Ma with subsequent rapid rock uplift from 16.5 to <6.3 Ma. This second scenario contradicts the recognized latest Eocene–Oligocene rapid exhumation of the Eastern Kunlun basement.In the southwestern Tarim Basin (section TB1, Fig. 3C), AFT data from the hanging wall of fault BF3 reveal rapid exhumation at 24–12 Ma and 12–6 Ma, which are interpreted as evidence of two-stage rock uplift of the Western Kunlun Range (Li et al., 2019). Corresponding growth structures are observed on the footwall of fault BF3 (Wang and Wang, 2016) (Fig. 3C). Following age model T1 (Sun and Liu, 2006), the growth strata indicate a prolonged tectonic quiescence period from 65.5 Ma to 5.2 Ma, with rapid rock uplift of the basement occurring during the Pliocene (>5.2 Ma to <2.6 Ma). This contradicts the proposed late Oligocene to Miocene rapid exhumation of the Western Kunlun Range based on LTT data. However, following age model T2 (Zheng et al., 2015), the growth strata suggest rapid faulting initiation along fault BF3 at ca. 22.6 Ma, consistent with the LTT record. Moreover, in section TB2 (Fig. 3D), AFT data from the hanging wall of fault BF4 show rapid exhumation and rock uplift of the Western Kunlun Range at 15–5 Ma (Cao et al., 2015). Growth strata are well preserved in the footwall of fault BF4. Following age model T1 (Sun and Liu, 2006), the pre-growth strata indicate prolonged tectonic quiescence from 65.5 Ma to 2.6 Ma while the growth strata suggest the onset of rapid rock uplift of the Western Kunlun Range at ca. 2.6 Ma (Fig. 3D). This scenario contradicts the Miocene to Pliocene rapid exhumation of the Western Kunlun Range derived from LTT data (Cao et al., 2015). However, following age model T2, the growth strata indicate a ca. 15 Ma initiation of rapid faulting, consistent with the exhumation history of the Western Kunlun basement based on LTT.The inconsistency between the LTT data in exhuming source regions and the age of growth-strata relationships in the adjacent sedimentary basins reveals that both “young” age models (Q2 and T1) for Cenozoic strata in the Qaidam and Tarim Basins, while magnetostratigraphically reasonable, are in conflict with the exhumation history of surrounding basement units. Our analysis hence indicates that the timing of syntectonic sedimentation is in very good agreement with age models Q1 and T2. Sedimentation initiated during the Paleocene–Eocene and was followed by intensified Oligocene–Miocene mountain building along the northern Tibetan Plateau margin. This episodic mountain building along the northern margin of the Tibetan Plateau highlights key features of out-of-sequence intra-plate deformation promoted by the post-collisional convergence.Because Paleogene marine incursions in the Tarim Basin do not simply align with eustatic sea-level changes (Figs. 4A–4C), recent studies have suggested a dominant role of tectonic loading and basin filling associated with the growth of the Pamir salient in the Proto-Paratethys Sea evolution (Kaya et al., 2019). However, Paleogene marine records were recently discovered farther east in the Qaidam Basin (Ma et al., 2022) indicating that the Proto-Paratethys Sea extended into Northern Tibet, which would have been located closer to the Tarim Basin, given the 300–500 km left-lateral offset along the Altyn Tagh fault since the Eocene (Cheng et al., 2016) (Texts S3 and S4; Fig. S4). As a result, Paleogene intracontinental deformation and associated modification in surface elevations along the northern Tibetan Plateau margin could have played a crucial role in driving the Proto-Paratethys Sea retreat in addition to deformation in the Pamir (Kaya et al., 2019). However, this hypothesis remains ambiguous due to the limited LTT data in Northern Tibet (Jepson et al., 2021) and the competing age models of syntectonic strata in the Qaidam Basin.Here we combine the newly constrained depositional age data from the Qaidam Basin with published LTT data sets, which together reflect Paleogene tectonic activity in Northern Tibet. We observe a consistent temporal correlation between tectonic activity and Proto-Paratethys Sea incursions (Figs. 4A–4D). Specifically, periods of tectonic quiescence in Northern Tibet at 57–56 Ma, 48–41 Ma, and 39–36 Ma correspond to the timing of the first, second, and third incursions of the Proto-Paratethys Sea, while peaks in tectonic activity at 56–48 Ma and 41–39 Ma coincide with the first, second, and third regressions (Fig. 4D). We propose that renewed acceleration of deformation in Northern Tibet and associated surface-elevation change promoted the intermittent retreat of the Proto-Paratethys Sea, while intervening deceleration of tectonic deformation facilitated Proto-Paratethys Sea incursions.The temporal coincidence between tectonism in Northern Tibet and Proto-Paratethys Sea regression highlights the previously underestimated role of tectonics in Northern Tibet in the retreat of the vast marine domain through uplift and basin infilling, which together with the northward indentation of the Pamir salient as well as the global sea-level fall during the Eocene-Oligocene transition (Kaya et al., 2019), led to the demise of the Proto-Paratethys Sea in Central Asia.This work was supported by the National Natural Science Foundation of China (U22B6002, 41888101, 41930213) and the Alexander von Humboldt Foundation. We thank editor Robert Holdsworth, Devon Orme, Ryan Leary, and an anonymous reviewer for constructive feedback that improved the manuscript.\",\"PeriodicalId\":12642,\"journal\":{\"name\":\"Geology\",\"volume\":\"40 51\",\"pages\":\"\"},\"PeriodicalIF\":4.8000,\"publicationDate\":\"2023-11-01\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Geology\",\"FirstCategoryId\":\"89\",\"ListUrlMain\":\"https://doi.org/10.1130/g51382.1\",\"RegionNum\":1,\"RegionCategory\":\"地球科学\",\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q1\",\"JCRName\":\"GEOLOGY\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Geology","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.1130/g51382.1","RegionNum":1,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"GEOLOGY","Score":null,"Total":0}
引用次数: 0

摘要

在缺乏全面的生物地层学或地质标志物(如火山层)的辐射测年的情况下,确定硅质碎屑大陆序列的年龄本身就具有挑战性。这一问题在当前关于中亚新生代地层年龄的辩论中得到了很好的例证,在这场辩论中,受非独特古地磁相关性约束的相互竞争的年龄模型被解释为反映青藏高原的生长及其对中亚气候变化的影响。在这里,我们提出了一种新的方法来评估竞争年龄模型,通过比较沉积物源区受低温热年代学约束的快速基底剥露的开始与相邻沉积槽中生长层的开始。我们首先在具有良好约束年龄模型的地区验证了该方法,然后将该方法应用于青藏高原北部的塔里木盆地和柴达木盆地。该分析结果表明,同构造沉积在古新世-始新世已经开始,随后在高原北缘渐新世-中新世造山活动加剧。基于这一精细的古近系构造史,我们进一步得出了藏北古近系的构造作用与原副特提斯海退缩之间的时间相关性。原副特蒂斯海是一个横跨欧亚大陆的主要水体,与气候和生物多样性变化密切相关。因此,我们强调了以前低估的藏北构造在古近纪原副特提斯海演化和消亡中的作用。由于大陆盆地的古地磁数据与地磁极性时间尺度(Ogg,2020)的相关性通常是非唯一的,在没有化石或放射性数据可供统计的火山灰层的情况下,单独的磁地层学可以导致大陆硅化碎屑序列的年龄模型显著不同(Lowe,2011)。这不可避免地导致了构造和古气候过程的时间、速率和持续时间的对比模型。这一根本挑战在中亚新生代陆相地层中得到了很好的体现(图1A–1E),在那里,相互竞争的年龄模型对青藏高原的生长具有强烈的分歧影响(Ji et al.,2017;Staisch et al.,2020;Wang et al.,2022)及其与亚洲古环境的联系,包括原副特提斯海的退缩,古近纪覆盖欧亚大陆大面积表面的主要水体(Bosboom et al.,2017;孙和刘,2006;郑et al.,2015)。新生代西藏造山带中最大的两个陆地盆地是塔里木盆地和柴达木盆地,其中包含了重要的造山和古气候档案(图1B)。柴达木盆地新生代地层的基底地层单元——鹿乐河组中的生长层和厚层砾岩(图1D)被解释为同造山期沉积物,记录了青藏北部在约60 Ma印度-亚洲碰撞中造山的开始(Ding et al.,2022;Yin et al.,2008)。然而,由于缺乏可直接获取数据的地质标志物和脊椎动物化石的稀缺性,已经提出了两种对比强烈的年龄模型,其基底年龄为约50Ma(Ji et al.,2017)或约30Ma(Wang et al.,2022),从而产生了青藏高原横向生长历史的竞争模型(Staisch等人,2020;王等人,2022;Yin等人,2008)。类似的争论集中在塔里木盆地新生代地层的沉积年龄上,一些人提出了Artux组的上新世年龄(孙和刘,2006),但另一些人认为同一单元的年龄为约27-15 Ma(Zheng et al.,2015)(图1E)。这种对风成岩和含石膏的Artux组的不同年龄分配导致了关于中亚干旱化时间的根本性争论(Licht et al.,2016;刘等人,2014;孙和刘,2006年)。此外,关于鲁乐河组沉积确切时间的知识影响了对原副特提斯海如何从中亚永久消退的解释(Bosboom et al.,2017;Ma et al.,2022)(图1B),进而影响了区域气候和生物多样性(Barbolini et al.,2020;Meijer et al.,2019)。后一种回归归因于海平面波动和远场构造对印度-亚洲碰撞的综合影响(Bosboom等人,2017;Burtman和Molnar,1993年;Dupont-Nivet等人,2007年;Kaya等人,2019)。然而,根据柴达木盆地同构造地层沉积的年龄模型,给出了截然不同的解释,西藏北部的古近系构造运动是否影响了原准特提斯海区域范围的回归,目前尚不清楚。 在这里,我们提出了一种简单而新颖的方法来评估火山灰岩和化石贫乏地层的年龄模型,方法是将这些沉积物的来源与汇点联系起来,并检查快速基底剥露与同构造沉积之间的时间关系。将该方法应用于塔里木盆地和柴达木盆地,对两个盆地古近系同构造地层的沉积年龄进行了约束,探讨了藏北古近系构造作用与原副特提斯海回归的关系。由低温热年代学(LTT)和生长层沉积确定的剥露幅度和速率对同构造盆地及其周围的范围剥露时间提供了限制,可以解释为反映断层活动的主要阶段。盆地边界断层附近生长地层的开始时间应与断层活动相关的剥露强化时间大致一致(图2A和2B)。相关地层单元的竞争年龄模型可以通过将LTT揭示的快速剥露和相关断层的开始与磁性地层对比定义的相关生长地层的拟议年龄进行比较来评估(图2A–2D)。为了验证这一方法,我们调查了伊朗扎格罗斯褶皱和逆冲带(以下简称扎格罗斯山脉)以及北美洲西部红宝石山脉变质核杂岩(以下简称红宝石山脉)的断层活动(补充材料1中的图S1和S2),其中同构造地层的沉积年龄通过辐射年龄很好地确定(图2E-2J)。然后,我们将这种方法应用于塔里木和柴达木盆地,以评估古近系同构造地层的磁地层学年龄。通过将这些来自柴达木盆地的新约束古近系构造活动数据与已发表的LTT记录相结合(He et al.,2018),我们探索了板内变形在驱动原准特提斯海入侵中的作用。补充资料S1、S2文给出了藏北古近系构造作用的地质背景和统计分析。在扎格罗斯山脉(图2E-2G),基尔库克断层上盘的磷灰石(U-Th)/He(AHe)数据记录了约8-7Ma的快速反向断层剥露(Koshnaw et al.,2020b),这与约8.0Ma基尔库克断层下盘生长层的形成相一致(Koshnawa et al.。20172020a)。在Ruby Mountains(图2H-2J),Ruby拆离体下盘的磷灰石裂变轨迹(AFT)和AHe年龄显示,在17–15 Ma时有快速正断层折返的证据(Colgan et al.,2010),与大约16 Ma时拆离体上盘生长层的起始相吻合(Lund-Snee et al.,2016;Satarugsa和Johnson,2000)。源区的快速剥露和基底冷却与相关沉积槽中生长地层的形成之间的一致性有力地支持了扎格罗斯山脉和红宝石山脉新生代晚期地层的拟议年龄模型,使我们能够将这种方法应用于中亚有争议的地层年龄模型。在柴达木盆地西北部,BF1断层上盘基岩的AFT数据显示,在50–30 Ma和30–10 Ma时,快速折返(图3A)。这些时间间隔被广泛解释为Altyn Tagh山脉两阶段岩石抬升的证据(Jolivet et al.,2001;Zhang et al.,2012)。如QB1剖面所示(图3A),BF1断层下盘出现两个生长结构序列,与基底的脉冲剥露一致(Cheng et al.,2021)。根据年龄模型Q1(Ji et al.,2017),生长地层分别表明古新世-始新世和渐新世-中新世期间的岩石隆起和基底剥露。这与LTT揭示的Altyn Tagh地下室的挖掘历史一致。然而,根据年龄模型Q2(Wang et al.,2022),生长地层表明脉冲式岩石抬升>25.5–23.5 Ma和16.5至25.5 Ma至16.5 Ma,随后快速岩石抬升从16.5至5.2 Ma至<2.6 Ma)。这与基于LTT数据提出的西昆仑山脉渐新世晚期至中新世快速剥露相矛盾。然而,根据年龄模型T2(Zheng et al.,2015),生长地层表明,在约22.6 Ma时,断层沿BF3快速启动,与LTT记录一致。此外,在TB2剖面(图3D)中,BF4断层上盘的AFT数据显示,西昆仑山脉在15-5 Ma时快速折返和岩石抬升(Cao et al.,2015)。BF4断层下盘发育地层保存完好。根据年龄模型T1(Sun和Liu,2006),生长前地层表明从65.5 Ma到2.6 Ma的长期构造静止,而生长地层表明西昆仑山脉在约2.6 Ma开始快速岩石抬升(图3D)。 这种情况与LTT数据得出的西昆仑山脉中新世至上新世快速剥露相矛盾(Cao et al.,2015)。然而,根据年龄模型T2,生长地层表明约15Ma的快速断层活动开始,与基于LTT的西昆仑基底剥露历史相一致。剥露源区的LTT数据与相邻沉积盆地的生长-地层关系年龄不一致表明,柴达木盆地和塔里木盆地新生代地层的“年轻”年龄模型(Q2和T1)在磁地层学上是合理的,与周围地下室单元的挖掘历史相冲突。因此,我们的分析表明,同构造沉积的时间与年龄模型Q1和T2非常一致。沉积始于古新世-始新世,随后青藏高原北部边缘渐新世-中新世造山活动加剧。青藏高原北缘的这种幕式造山突出了碰撞后辐合促进的板内错序变形的关键特征。由于塔里木盆地的古近系海洋入侵并不简单地与海平面升降变化一致(图4A–4C),最近的研究表明,与帕米尔凸起的生长相关的构造载荷和盆地填充在原副特提斯海演化中起着主导作用(Kaya et al.,2019)。然而,最近在柴达木盆地更东部发现了古近系海洋记录(Ma et al.,2022),表明原准特提斯海延伸到西藏北部,考虑到自始新世以来沿阿尔金-塔格断层的300–500公里左侧偏移,西藏北部本应更靠近塔里木盆地(Cheng et al.,2016)(文本S3和S4;图S4)。因此,除了帕米尔高原的变形外,青藏高原北部边缘古近系陆内变形和地表高程的相关变化可能在推动原副特提斯海退缩方面发挥了关键作用(Kaya et al.,2019)。然而,由于藏北LTT数据有限(Jepson et al.,2021)和柴达木盆地同构造地层的年龄模型相互竞争,这一假设仍然模糊不清。在这里,我们将柴达木盆地新约束的沉积年龄数据与已发表的LTT数据集相结合,这些数据集共同反映了藏北古近系构造活动。我们观察到构造活动与原副特提斯海入侵之间存在一致的时间相关性(图4A–4D)。具体而言,藏北57–56 Ma、48–41 Ma和39–36 Ma的构造平静期对应于前副特提斯海第一次、第二次和第三次入侵的时间,而56–48 Ma和41–39 Ma的构造活动峰值与第一次、第一次和第二次回归相吻合(图4D)。我们认为,藏北变形的再次加速和相关的地表高程变化促进了原副特提斯海的间歇性后退,而构造变形的介入减速促进了原准特提斯海入侵。藏北构造运动与原准特提斯海回归之间的时间重合,突显了藏北构造在通过隆起和盆地填充后退广阔海洋领域中先前被低估的作用,这项工作得到了国家自然科学基金(U22B600241888101141930213)和亚历山大·冯·洪堡基金会的支持。我们感谢编辑Robert Holdsworth、Devon Orme、Ryan Leary和一位匿名审稿人的建设性反馈,他们改进了手稿。
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Linking source and sink: The timing of deposition of Paleogene syntectonic strata in Central Asia
Determining the age of siliciclastic continental sequences in the absence of comprehensive biostratigraphy or radiometric dating of geological markers (e.g., volcanic layers) is inherently challenging. This issue is well exemplified in the current debate on the age of Cenozoic terrestrial strata in Central Asia, where competing age models constrained by non-unique paleomagnetic correlations are interpreted to reflect the growth of the Tibetan Plateau and its impact on Central Asian climate change. Here we present a new approach to evaluate competing age models by comparing the onset of rapid basement exhumation constrained by low-temperature thermochronology in the sediment source region with the initiation of growth strata in the adjacent sedimentary sink. We first validate this method in regions with well-constrained age models and subsequently apply this approach to the Tarim and Qaidam Basins in the northern Tibetan Plateau. The results of this analysis show that syntectonic sedimentation had already initiated during the Paleocene–Eocene and was followed by intensified Oligocene–Miocene mountain building along the northern margin of the plateau. Based on this refined Paleogene tectonic history, we further arrive at a temporal correlation between Paleogene tectonism in Northern Tibet and the retreat of the Proto-Paratethys Sea, a major water body that extended across Eurasia and was closely associated with climatic and biodiversity changes. We thus highlight the previously underestimated role tectonics in Northern Tibet had in the evolution and demise of the Proto-Paratethys Sea during the Paleogene.Because correlation of paleomagnetic data from continental basins to the Geomagnetic Polarity Time Scale (Ogg, 2020) is commonly non-unique, magnetostratigraphy alone can lead to dramatically different age models for continental siliciclastic sequences in the absence of fossils or radiometrically datable volcanic ash layers (Lowe, 2011). This inevitably leads to contrasting models for the timing, rates, and duration of tectonic and paleoclimatic processes. This fundamental challenge is well exemplified in Cenozoic terrestrial strata in Central Asia (Figs. 1A–1E), where competing age models have strongly diverging implications for the growth of the Tibetan Plateau (Ji et al., 2017; Staisch et al., 2020; Wang et al., 2022) and its association with Asia paleo-environments including the retreat of the Proto-Paratethys Sea, a major water body that covered large surfaces of Eurasia during the Paleogene (Bosboom et al., 2017; Sun and Liu, 2006; Zheng et al., 2015).The two largest terrestrial basins in the Cenozoic Tibetan orogen are the Tarim and Qaidam Basins, which contain critical archives of mountain building and paleoclimate (Fig. 1B). The growth strata and thick-bedded conglomerates in the Lulehe Formation, the basal stratigraphic unit of Cenozoic strata in the Qaidam Basin (Fig. 1D), are interpreted as synorogenic sediments that record the initiation of mountain building in Northern Tibet in response to the ca. 60 Ma India-Asia collision (Ding et al., 2022; Yin et al., 2008). However, due to a lack of directly datable geologic markers and the scarcity of vertebrate fossils, two strongly contrasting age models, with a basal age of either ca. 50 Ma (Ji et al., 2017) or ca. 30 Ma (Wang et al., 2022), have been proposed for the depositional age of the Lulehe Formation, resulting in competing models for the lateral growth history of the Tibetan Plateau (Staisch et al., 2020; Wang et al., 2022; Yin et al., 2008). A similar debate centers around the depositional age of Cenozoic strata in the Tarim Basin, where some have proposed a Pliocene age for the Artux Formation (Sun and Liu, 2006) but others have assigned ages of ca. 27–15 Ma for the same unit (Zheng et al., 2015) (Fig. 1E). This differing age assignment on the eolian- and gypsum-bearing Artux Formation has led to a fundamental debate about the timing of aridification in Central Asia (Licht et al., 2016; Liu et al., 2014; Sun and Liu, 2006). In addition, knowledge about the exact timing of deposition of Lulehe Formation affects interpretations on how the Proto-Paratethys Sea retreated permanently from Central Asia (Bosboom et al., 2017; Ma et al., 2022) (Fig. 1B) and in turn impacted the regional climate and biodiversity (Barbolini et al., 2020; Meijer et al., 2019). The latter regression was attributed to the combined effect of eustatic fluctuations and far-field tectonics in response to the India-Asia collision (Bosboom et al., 2017; Burtman and Molnar, 1993; Dupont-Nivet et al., 2007; Kaya et al., 2019). However, given strikingly different interpretations depending on the age model for the deposition of syntectonic strata in the Qaidam Basin, it remains elusive whether Paleogene tectonism along Northern Tibet impacted regression in the areal extent of the Proto-Paratethys Sea.Here we present a simple yet novel approach to assessing age models in tephra- and fossil-poor strata by linking source to sink of such sediments and examining the temporal relationship between rapid basement exhumation and syntectonic sedimentation. Applying this approach to the Tarim and Qaidam Basins, we constrain the depositional age of Paleogene syntectonic strata in both basins and explore the correlation between Paleogene tectonism in Northern Tibet with the regression of the Proto-Paratethys Sea.Magnitudes and rates of exhumation determined by low-temperature thermochronology (LTT) and growth-strata deposition provide constraints on the timing of range exhumation in and around syntectonic basins that can be interpreted to reflect major phases of fault activity. The onset timing of growth strata in the immediate vicinity of a basin-bounding fault should largely coincide with the timing of intensified exhumation linked to fault activity (Figs. 2A and 2B). Competing age models for the associated stratigraphic units can be evaluated by comparing the onset of rapid exhumation and correlative faulting revealed by LTT with the proposed age of associated growth strata defined by magnetostratigraphic correlation (Figs. 2A–2D). To validate this approach, we investigate fault activity in the Zagros fold-and-thrust belt (hereafter Zagros Mountains) in Iran and the Ruby Mountains metamorphic core complex (hereafter Ruby Mountains) in western North America (Figs. S1 and S2 in the Supplemental Material1), where the depositional ages of the syntectonic strata are well established by radiometric ages (Figs. 2E–2J). We then apply this approach to the Tarim and Qaidam Basins to evaluate the debated magnetostratigraphic ages of Paleogene syntectonic strata. By integrating these newly constrained Paleogene tectonism data from the Qaidam Basin with published LTT records (He et al., 2018), we explore the role of intra-plate deformation in driving the Proto-Paratethys Sea incursions. Geological background and statistical analyses of the Paleogene tectonism in Northern Tibet are given in Texts S1 and S2 in the Supplemental Material.In the Zagros Mountains (Figs. 2E–2G), apatite (U-Th)/He (AHe) data from the hanging wall of the Kirkuk fault record rapid reverse-faulting exhumation at ca. 8–7 Ma (Koshnaw et al., 2020b), which is consistent with the initiation of growth strata in the footwall of the Kirkuk fault at ca. 8.0 Ma (Koshnaw et al., 2017, 2020a). In the Ruby Mountains (Figs. 2H–2J), apatite fission-track (AFT) and AHe ages from the footwall of the Ruby detachment show evidence of rapid normal-faulting exhumation at 17–15 Ma (Colgan et al., 2010), coinciding with the initiation of growth strata in the hanging wall of the detachment at ca. 16 Ma (Lund Snee et al., 2016; Satarugsa and Johnson, 2000). These consistencies between the rapid exhumation and basement cooling in the source area and the initiation of growth strata in the associated sedimentary sink lend strong support to the proposed age model of the late Cenozoic strata in the Zagros and Ruby Mountains, allowing us to apply this approach to debated stratigraphic age models in Central Asia.In the northwestern Qaidam Basin, AFT data from the basement rocks in the hanging wall of fault BF1 show rapid exhumation at 50–30 Ma and 30–10 Ma (Fig. 3A). These time intervals are widely interpreted as evidence for a two-stage rock uplift of the Altyn Tagh Range (Jolivet et al., 2001; Zhang et al., 2012). As shown on section QB1 (Fig. 3A), two sequences of growth structures occur in the footwall of fault BF1 that are consistent with pulsed exhumation of the basement (Cheng et al., 2021). Following age model Q1 (Ji et al., 2017), the growth strata indicate rock uplift and basement exhumation during the Paleocene–Eocene and Oligocene–Miocene, respectively. This is consistent with the exhumation history of the Altyn Tagh basement revealed by LTT. However, following age model Q2 (Wang et al., 2022), the growth strata indicate pulsed rock uplift at >25.5–23.5 Ma and 16.5 to <6.3 Ma, separated by tectonic quiescence from 23.5 Ma to 16.5 Ma. This second scenario contradicts the Miocene exhumation of the Altyn Tagh basement indicated by LTT data (Jolivet et al., 2001; Zhang et al., 2012).In the southern Qaidam Basin, AFT and AHe data from the basement on the hanging wall of fault BF2 (Fig. 3B) show rapid exhumation at ca. 35–25 Ma, indicating rapid exhumation of the Eastern Kunlun Range from the latest Eocene to Oligocene (Clark et al., 2010; Li et al., 2021). Growth strata (section QB2, Fig. 3B) are developed in the footwall of fault BF2 (Cheng et al., 2021), suggesting a corresponding rock uplift and exhumation of the Eastern Kunlun Range. Following age model Q1, the occurrence of the growth strata indicates rapid rock uplift and exhumation of the Eastern Kunlun basement from 35.5 to <8.1 Ma, consistent with the exhumation history of the Eastern Kunlun basement revealed by LTT. However, following age model Q2, the resulting age of the growth strata requires tectonic quiescence from >25.5 Ma to 16.5 Ma with subsequent rapid rock uplift from 16.5 to <6.3 Ma. This second scenario contradicts the recognized latest Eocene–Oligocene rapid exhumation of the Eastern Kunlun basement.In the southwestern Tarim Basin (section TB1, Fig. 3C), AFT data from the hanging wall of fault BF3 reveal rapid exhumation at 24–12 Ma and 12–6 Ma, which are interpreted as evidence of two-stage rock uplift of the Western Kunlun Range (Li et al., 2019). Corresponding growth structures are observed on the footwall of fault BF3 (Wang and Wang, 2016) (Fig. 3C). Following age model T1 (Sun and Liu, 2006), the growth strata indicate a prolonged tectonic quiescence period from 65.5 Ma to 5.2 Ma, with rapid rock uplift of the basement occurring during the Pliocene (>5.2 Ma to <2.6 Ma). This contradicts the proposed late Oligocene to Miocene rapid exhumation of the Western Kunlun Range based on LTT data. However, following age model T2 (Zheng et al., 2015), the growth strata suggest rapid faulting initiation along fault BF3 at ca. 22.6 Ma, consistent with the LTT record. Moreover, in section TB2 (Fig. 3D), AFT data from the hanging wall of fault BF4 show rapid exhumation and rock uplift of the Western Kunlun Range at 15–5 Ma (Cao et al., 2015). Growth strata are well preserved in the footwall of fault BF4. Following age model T1 (Sun and Liu, 2006), the pre-growth strata indicate prolonged tectonic quiescence from 65.5 Ma to 2.6 Ma while the growth strata suggest the onset of rapid rock uplift of the Western Kunlun Range at ca. 2.6 Ma (Fig. 3D). This scenario contradicts the Miocene to Pliocene rapid exhumation of the Western Kunlun Range derived from LTT data (Cao et al., 2015). However, following age model T2, the growth strata indicate a ca. 15 Ma initiation of rapid faulting, consistent with the exhumation history of the Western Kunlun basement based on LTT.The inconsistency between the LTT data in exhuming source regions and the age of growth-strata relationships in the adjacent sedimentary basins reveals that both “young” age models (Q2 and T1) for Cenozoic strata in the Qaidam and Tarim Basins, while magnetostratigraphically reasonable, are in conflict with the exhumation history of surrounding basement units. Our analysis hence indicates that the timing of syntectonic sedimentation is in very good agreement with age models Q1 and T2. Sedimentation initiated during the Paleocene–Eocene and was followed by intensified Oligocene–Miocene mountain building along the northern Tibetan Plateau margin. This episodic mountain building along the northern margin of the Tibetan Plateau highlights key features of out-of-sequence intra-plate deformation promoted by the post-collisional convergence.Because Paleogene marine incursions in the Tarim Basin do not simply align with eustatic sea-level changes (Figs. 4A–4C), recent studies have suggested a dominant role of tectonic loading and basin filling associated with the growth of the Pamir salient in the Proto-Paratethys Sea evolution (Kaya et al., 2019). However, Paleogene marine records were recently discovered farther east in the Qaidam Basin (Ma et al., 2022) indicating that the Proto-Paratethys Sea extended into Northern Tibet, which would have been located closer to the Tarim Basin, given the 300–500 km left-lateral offset along the Altyn Tagh fault since the Eocene (Cheng et al., 2016) (Texts S3 and S4; Fig. S4). As a result, Paleogene intracontinental deformation and associated modification in surface elevations along the northern Tibetan Plateau margin could have played a crucial role in driving the Proto-Paratethys Sea retreat in addition to deformation in the Pamir (Kaya et al., 2019). However, this hypothesis remains ambiguous due to the limited LTT data in Northern Tibet (Jepson et al., 2021) and the competing age models of syntectonic strata in the Qaidam Basin.Here we combine the newly constrained depositional age data from the Qaidam Basin with published LTT data sets, which together reflect Paleogene tectonic activity in Northern Tibet. We observe a consistent temporal correlation between tectonic activity and Proto-Paratethys Sea incursions (Figs. 4A–4D). Specifically, periods of tectonic quiescence in Northern Tibet at 57–56 Ma, 48–41 Ma, and 39–36 Ma correspond to the timing of the first, second, and third incursions of the Proto-Paratethys Sea, while peaks in tectonic activity at 56–48 Ma and 41–39 Ma coincide with the first, second, and third regressions (Fig. 4D). We propose that renewed acceleration of deformation in Northern Tibet and associated surface-elevation change promoted the intermittent retreat of the Proto-Paratethys Sea, while intervening deceleration of tectonic deformation facilitated Proto-Paratethys Sea incursions.The temporal coincidence between tectonism in Northern Tibet and Proto-Paratethys Sea regression highlights the previously underestimated role of tectonics in Northern Tibet in the retreat of the vast marine domain through uplift and basin infilling, which together with the northward indentation of the Pamir salient as well as the global sea-level fall during the Eocene-Oligocene transition (Kaya et al., 2019), led to the demise of the Proto-Paratethys Sea in Central Asia.This work was supported by the National Natural Science Foundation of China (U22B6002, 41888101, 41930213) and the Alexander von Humboldt Foundation. We thank editor Robert Holdsworth, Devon Orme, Ryan Leary, and an anonymous reviewer for constructive feedback that improved the manuscript.
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来源期刊
Geology
Geology 地学-地质学
CiteScore
10.00
自引率
3.40%
发文量
228
审稿时长
6.2 months
期刊介绍: Published since 1973, Geology features rapid publication of about 23 refereed short (four-page) papers each month. Articles cover all earth-science disciplines and include new investigations and provocative topics. Professional geologists and university-level students in the earth sciences use this widely read journal to keep up with scientific research trends. The online forum section facilitates author-reader dialog. Includes color and occasional large-format illustrations on oversized loose inserts.
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