A giant lacustrine flood‐related turbidite system in the Triassic Ordos Basin, China: Sedimentary processes and depositional architecture

Chen, Peng; Xian, Benzhong; Li, Meijun; Liu, Xiaowei; Wu, Qian; Zhang, Wenmiao; Wang, Junhui; Zhen, Wang; Jian-ping, Liu

doi:10.1111/sed.12891

Cited by 18 publications

(8 citation statements)

References 74 publications

(175 reference statements)

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“…Hyperpycnites in depression basins have been widely reported, such as that in the Ordos Basin (Chen et al, 2021; Xian et al, 2018; Yang et al, 2017), and the Songliao Basin (Dou et al, 2021; Pan et al, 2017) in China. This study demonstrated that there are many differences between hyperpycnites in rift basins and depression basins (Yang et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

“…This study demonstrated that there are many differences between hyperpycnites in rift basins and depression basins (Yang et al, 2020). Hyperpycnites in depression basins are usually dominated by fine‐grained sandstone, with distinct channel‐lobe system and long transport distance more than 100 km (Chen et al, 2021; Dou et al, 2021; Pan et al, 2017; Xian et al, 2018; Yang et al, 2017). However, hyperpycnites in rift basins are characterized by a wide range of grain size range from gravel to fine‐grained sands (Figure 3) (Liu et al, 2021; Yang et al, 2019, 2020; Yuan et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…In lacustrine rift basins, hyperpycnal flows are more likely to occur because of strong tectonic activity, small basin area, low water density, large terrain height difference and development of small rivers (Chen et al, 2021;Dou et al, 2021;Mulder et al, 2003;Mulder & Chapron, 2011;Pan et al, 2017;Soyinka & Slatt, 2008;Xian et al, 2018;Yang et al, 2017Yang et al, , 2020Zavala, 2020;Zavala et al, 2006Zavala et al, , 2011. It thus provide a natural laboratory to resolve the controversies about the identification marks and transport evolution processes of hyperpycnal flow deposits.…”

Section: Introductionmentioning

confidence: 99%

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Sedimentary characteristics and depositional model of hyperpycnites in the gentle slope of a lacustrine rift basin: A case study from the third member of the Eocene Shahejie Formation, Bonan Sag, Bohai Bay Basin, Eastern China

et al. 2023

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Hyperpycnal flow deposits, one of the most important deep‐water gravity‐flow deposits in lacustrine basins, have become the research focus in recent years. However, the sedimentary characteristics and depositional model of hyperpycnal flow deposits in lacustrine basins remain unclear due to the differences of depositional settings between lacustrine and marine environments. Hyperpycnal flow deposits observed in the middle of the third member of the Shahejie Formation (Es3z) in the Bonan Sag, Bohai Bay Basin, Eastern China, provide a rare case study to reveal the characteristics and depositional model in lacustrine basins. For the first time, detailed core analysis, high‐resolution 3D seismic data, petrology and grain size analysis were used to unravel the characteristics and depositional model of hyperpycnal flow deposits in this study. Twelve lithofacies, six bed types and four bedsets (corresponding to feeder channel, distributary channel, levee and lobe) were recognized from detailed facies analysis. Plant fragment, an important identification mark for hyperpycnal flow deposits, can be classified into three types: completely broken plant fragments, partially broken plant fragments and complete leaves. The proximal part of the deposit develops a small amount of scattered and completely broken plant fragments in massive or spaced stratified pebbly sandstone and massive sandstone due to strong erosion of sustained high‐density turbidity current. The medial part of the deposit is dominated by laminated partially broken plant fragments in planar laminated or rippled sandstone due to suspended settling of sustained high‐density turbidity current and quasi‐steady low‐density turbidity current. Layered partially broken plant fragments with some complete leaves are common in the upper part mud rich division of hybrid event bed and laminated siltstone in the distal part of the deposit. The distribution pattern of hyperpycnites is controlled comprehensively by palaeogeomorphy and sediment supply. Palaeogullies determine the provenance direction of hyperpycnal flow. The formation of synsedimentary faults and troughs control the transport routing patterns. Local micro‐palaeogeomorphy and depression areas further restrict the distribution of sand bodies. During the early stage of deposition with insufficient sediment supply, sediments are transported to the deep basin along confined faulted troughs forming elongated sandy bodies. During the late stage of deposition with sufficient sediment supply, sediments are transported to the deep basin without confinement accumulating fan‐shaped sandy bodies. This study offers insight for enhancing the recognition criteria of hyperpycnites, as well as their depositional model in lacustrine basins.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sedimentary characteristics and depositional model of hyperpycnites in the gentle slope of a lacustrine rift basin: A case study from the third member of the Eocene Shahejie Formation, Bonan Sag, Bohai Bay Basin, Eastern China

et al. 2023

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“…For these reasons, hyperpycnal flow deposits (‘hyperpycnites’) are commonly described from various lacustrine and glacio‐deltaic successions, reflecting the favourable conditions for dense underflows to form in these environments (e.g. Nemec et al ., 1999; Zavala et al ., 2006; Girard et al ., 2012; Yang et al ., 2017; Cao et al ., 2018; Bellwald et al ., 2020; Chen et al ., 2021). Despite recent developments in the surveillance of naturally occurring turbidity currents (Clare et al ., 2016; Azpiroz‐Zabala et al ., 2017; Hage et al ., 2019; Maier et al ., 2019; Heijnen et al ., 2020; Heerema et al ., 2022; Pope et al ., 2022; Talling et al ., 2022), monitoring data of hyperpycnal flows in the marine realm is relatively sparse.…”

Section: Introductionmentioning

confidence: 99%

“…In addition, there is a growing body of literature describing hyperpycnites in ancient and modern submarine lobes, suggesting that hyperpycnal flows may transfer sand into deep‐water environments (e.g. Mutti et al ., 2003; Bourget et al ., 2010; Zavala et al ., 2012; Warrick et al ., 2013; Chen et al ., 2021). This is enigmatic, because it has been shown that hyperpycnal flows entering marine basins typically deposit their sandy load near the river mouth (e.g.…”

Section: Introductionmentioning

confidence: 99%

Deep‐water sand transfer by hyperpycnal flows, the Eocene of Spitsbergen, Arctic Norway

Grundvåg

Helland‐Hansen

Johannessen³

et al. 2023

Sedimentology

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Flood‐generated hyperpycnal flows are dense, sediment‐laden, turbulent flows that can form long‐lived, bottom‐hugging turbidity currents, which undoubtedly transport large volumes of fine‐grained sediments into the ocean. However, their ability in transferring sand into deep‐water basins is debated. This study presents sedimentological evidence of sandy hyperpycnal flow deposits (hyperpycnites) in a series of basin floor lobe complexes associated with a progradational shelf margin in the Eocene of Spitsbergen, Arctic Norway. Four coexisting types of sediment gravity flow deposits are recognized: (i) sandy hyperpycnites deposited by quasi‐steady hyperpycnal flows; (ii) turbidites deposited by waning, surge‐type turbidity currents; (iii) hybrid event beds deposited by transitional flows; and (iv) mass transport deposits emplaced during rare slope failures. The abundance of thick‐bedded massive sandstones, frequent bed amalgamation, the distribution of hyperpycnites across the lobes and the abundance and systematic occurrence of plant‐rich hybrid event beds and associated climbing ripple cross‐laminated beds in the lobe fringes, suggest that hyperpycnal flow was the most important mechanism driving lobe progradation. Shelf‐edge positioned fluvial channels linked to the basin floor lobe complexes via deeply incised, sandstone‐filled slope channels, suggest that rivers fed directly onto the slopes where their dense, sand‐laden discharges readily generated quasi‐steady hyperpycnal flows that regularly reached the basin floor. The composite architecture and complex waxing–waning flow facies configuration of the hyperpycnites is consistent with sustained and concomitant suspension and traction deposition under fluctuating subcritical to supercritical conditions. Similar sandstone beds occur on the clinoform slopes, indicating that the hyperpycnal flows operated likewise on the slope. Plant‐rich hybrid event beds indicate transformation of initially turbulent flows by relative enrichment of clay and plant material via progressive sand deposition to such an extent that it suppressed turbulence. The multi‐faceted character of the hyperpycnites reported here, challenges traditional beliefs that hyperpycnites assumingly preserve the waxing–waning signal of single‐peaked floods.

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Characterization of tight sandstone and sedimentary facies using well logs and seismic inversion in lacustrine gravity-flow deposits

Liu,

Yue,

et al. 2024

Journal of Asian Earth Sciences

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A giant lacustrine flood‐related turbidite system in the Triassic Ordos Basin, China: Sedimentary processes and depositional architecture

Cited by 18 publications

References 74 publications

Sedimentary characteristics and depositional model of hyperpycnites in the gentle slope of a lacustrine rift basin: A case study from the third member of the Eocene Shahejie Formation, Bonan Sag, Bohai Bay Basin, Eastern China

Sedimentary characteristics and depositional model of hyperpycnites in the gentle slope of a lacustrine rift basin: A case study from the third member of the Eocene Shahejie Formation, Bonan Sag, Bohai Bay Basin, Eastern China

Deep‐water sand transfer by hyperpycnal flows, the Eocene of Spitsbergen, Arctic Norway

Characterization of tight sandstone and sedimentary facies using well logs and seismic inversion in lacustrine gravity-flow deposits

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