Cisuralian (Lower Permian) sequence successions and depositional characters at Nashui of Luodian County, southern Guizhou. Fossils mainly shown at the positions of their first appearances (FAD).

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Permian sequence stratigraphy of slope facies in southern Guizhou and chronostratigraphic correlation

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Apr 2012

The Permian in slope facies area of southern Guizhou consists of 16 third order sequences, which can be grouped as four sequence sets and further into two mesosequences. Most of them are delineated by conformable or submarine erosion surfaces, and well controlled by conodont and fusulinid zones. Four important sea-level falls are recognized in the...

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... Sequence subdivision and boundary characters As the studied area is paleogeographically at the lower part of carbonate platform foreslope to basin margin, most of the recognized sequence boundaries either manifest as conformable surfaces or as submarine erosions. Unequivocal subaerial erosion has only been observed at the base of PSq7, of the upper part of the Qixia Formation ( fig. 4). Beneath the wavy erosional surface, a caliche of 15 cm thick exists on thick bedded bioclastic calcarenite. Above the surface, a clay bed up to 30 cm thick shows up, indicating terrestrial weathering. The lower LST of PSq7 sequence is characterized by 1.5 m gravel-bearing coarse lithic sandstone to calcarenite of compound composition. The gravel and sands are mainly of quartzite and chert, generally 1 3 mm in diameter, well rounded but poorly sorted. The upper LST consists of thick bedded bioclastic packstone 10 m thick. The basal boundaries of the sequences PSq1, PSq2 and PSq3 are delineated by submarine erosion surfaces (fig. 4). Slight truncations have been recognized there, but no carbonate breccias of debris flow origin are found in their LSTs. Definite submarine erosions are identified respectively at the bases of sequences PSq8 and PSq11, where the LSTs are characterized by massive calcirudite of debris flow origin and clearly truncate the underlying bedded limestone. These aforementioned sequences should be taken as type I. The other sequence boundaries seem to be mainly conformable surfaces, though some of them have been found with distal gravity flow deposits in the LST or SMST. They are chiefly recognized by parasequence stacking patterns and interior facies architectures, as well as by abrupt change in deposition around the boundary. These may tentatively be regarded as type II sequences in this paper, as their spatial distribution has not been properly investigated yet. 3.1.1 Ss1 sequence set. It is made up of the upper part of the Upper Carboniferous and the lower Cisuralian (fig. 4). Two Permian sequences (PSq1 and PSq2) are included in this set. According to fossil zonation [1 4] and the current Permian subdivision scheme [5,6,13] , PSq1 straddles C/P boundary (fig. 4), with its FFS quite close to the FAD of Streptognathodus nodulinearis , which is slightly above the C/P boundary [4,6,16] . Its LST is composed of 15 m packstone, in which fine intraclastic beds of gravity flow origin have been observed. The intraclast is generally 2 5 mm in diameter, with the maximum size up to 1 2 cm and volume 5% 15%. The sequence boundary of PSq1 (fig. 4) is about 8 m below the FAD of Streptognathodus wabaunensis , but 3 m higher than the FAD of Streptognathodus elongatus . The S. wabaunensis - S. nodulinearis zone was taken as the lowermost Zisongian [3,6] and was also the basal zone for the Asselian in the Urals [17] . At Aidaralash Creek of northern Kazakhstan, the GSSP for C/P boundary, the base of Permian is marked by the FAD of Streptognathodus isolatus , which is thought to be in the evolutionary morphocline of S.wabaunensis and is about 6 m above the FAD of the latter [13,18] . The basal boundary of PSq2 is just between the Streptognathodus barskovi zone and Mesogondolella dentiseparata zone. This position is regarded as a turning point in conodont evolution, when conodonts of Carboniferous type were completely replaced by those of the Permian type [19,20] . PSq1 and PSq2 may be taken as the highstand deposits of Ss1 sequence set and were formed during the medium-term sea-level lowering. 3.1.2 Ss2 sequence set. It comprises four third order sequences (PSq3 PSq6) and extends from the Sweetognathodus whitei zone to the lower part of Sw . aff. hanzhongensis zone or the fusulinid Neoschwagerina simplex-Praesumatrina neoschwagerinoides zone (figs. 3 and 4), roughly covering the interval of the late Artinskian to middle Kungurian [13] . The lower boundary of PSq3 is stamped by a submarine truncation surface. Above the surface, 8 m massive bioclastic packstone occurs as LST, quite distinct from the underlying medium bedded wackstone. The FFS of PSq3 coincides with the base of the Nashui Formation. Sweetognathodus whitei has its FAD 2.2 m below the FFS. The MFS of PSq3 marks one of the most significant transgressions in the Permian and is also accompanied by a faunal turnover, starting the Kungurian. The other three sequences in this set are all well controlled by biozones (figs. 3 and 4) and can be correlated directly with those recognized at Laibin, central Guangxi [19,20] . It is worth noting that in the sequence PSq4, conodont Mesogondolella cf. gujioensis and fusulinid Brevaxina dyhrenfurthi occur just above the MFS (fig. 4), marking the beginning of the Luodianian Stage or the Chihsian Subseries [5,6] . 3.1.3 Ss3 sequence set. It comprises 5 sequences (PSq7 PSq11) and consists of the upper Qixia Formation and Maokou Formation, roughly equivalent to upper Kungurian and Guadalupian. According to fusulinid zonation [4,5] , the sequence boundary of PSq7 is 8 m above the base of Neoshwagerina simplex-Praesumatrina neoschwagerinoides zone, and about 20 m above the FAD of Sweetognathodus aff. hanzhongensis . This boundary represents one of the most significant sea- level falls in the Permian and probably had resulted in important stratal hiatus in shelf region. In the LST of PSq8, abundant fusulinids, such as Afghanella tereshkovae, Neoschwagerina cf. craticulifera and Verbeekina spp. occur, suggesting the Maokouan age. According to conodonts, however, it is far below the FAD of Jinogondonella nankingensis which has been taken as the lowermost zone of Guadalupian [6,13,19] and occurs at the MFS of PSq9 (figs. 3 and 4). The other three sequences, though yielding some conodonts, are mainly dated by fusulinids. Their correlation with biozones is illustrated in figs. 3 and 5. It is worth noting that the strata equivalent to PSq7 and probably also PSq8 seem to be absent in the Urals and in the southwest United States. In these two regions, the Mesogondonella idahoensis zone is generally taken as the upper Kungurian [3, 16] , while Jinogondonella nankingensis zone as the lowermost Guadalupian. In Nashui section, however, the sequences PSq7 and PSq8 exist between these two zones (figs. 3 and 4). J. nankingensis has its FAD slightly above the MFS of PSq9 (fig. 5) and M. idahoensis has its FAD at the top of bed 56, just below the base of PSq6. In PSq7 and PSq8, three conodont zones, Sweetognathodus aff hanzhongensis, S. hanzhongensis-S. subsymmetricus and Mesogondonella aff. nankingensis , are clearly shown in succession (figs. 3 and 4). As the sequence boundary of PSq7 marks a significant sea-level fall world wide, we suspect that the strata equivalent to PSq7 and PSq8 might be absent in the regions for lower sea level. 3.1.4 Ss4 sequence set. It includes five third-order sequences (PSq12 PSq16). In the Nashui section only the lower three have been studied in detail, all of them delineated by conformable surfaces at bottom. Owing to the siliciclastic and siliceous deposits, as well as deep-water environments, fossils are rare in this set. The base of PSq12 may lay in the upper Metadoliolina multivoluta zone (fig. 5). The FFS of PSq12 is in good accordance with the base of the Naqing Formation. A correlation with the sequences in Laibin, central Guangxi [19 21] indicates that the sequence boundary of PSq12 lays at the middle Jinogondonella xuanhanensis zone and its FFS in the lower Clarkina postbitteri zone, only 0.6 m above the FAD of this species ...

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... The four sections in fig. 6 constitute a transverse profile from the platform margin to basin and two sequences can be recognized. In the Xinyuan section, the Changxing Formation consists typically of massive sponge-reef limestone, suggesting a rimmed platform margin background. In this section, LST has only been observed in PSq15, where it is composed of collapsed lime breccia from the platform margin reef. Southward to Liugao and Xiayuan, slump lime breccia is very well developed, pointing to a position at carbonate platform foreslope. Gravel in the breccia is generally 2 10 cm in diameter, with the maximum up to 40 cm. In these two sections, HST is often incomplete, being truncated or partially eroded away by the overlying LST slumps. In the Shaiwa section, which is in the basin, deposits are characterized by siliceous shale, cherts, claystone and siltstone. Two major submarine erosions are observed at the lower and upper parts of the 4th Member of Shaiwa Group (fig. 6), forming the sequence boundaries of PSq15 and TSq1 respectively. About 13 m gravel-bearing siltstone to fine-gained lithic sandstone was found in the middle of the 4th Member. This gravel-bearing lithic sandstone bed is of gravity flow origin and may be taken as the LST of PSq16 without much doubt, but no eminent submarine erosion or truncation was recognized at the bottom. It is worth noting that, from the platform margin to basin, LST slumps (PSq15 to TSq1) show a clear tendency of increase in thickness, while the total thickness of each sequence continuously decreasing toward the basin. At the platform margin (e.g. Xinyuan section), LST exists only in sequence PSq15 and is characterized by collapsed lime breccia, but is completely absent in PSq16 and TSq1, both of which are marked by subaerial erosion surfaces at bottom and begin with FFS. Basinward LSTs are well developed in all the other three sequences. According to the fossils documented in the Shaiwa section , the lower boundary of PSq15 sits at the uppermost part of Wujiapingian and FFS is in accordance with the lowermost Changhsingian. Similarly, the base of TSq1 also lays in the uppermost Changhsingian and the FFS marks the beginning of the Triassic. This phenomenon seems quite common and has been noted widely at the Permian/Triassic boundary [22] . This may imply that new transgression provides the best opportunity for the dispersal of a new fauna and FFS can be used as an event marker in stratigraphic correlation and an important reference in fine-tuning bio-chronozones. 3.2 Sea-level change cycles The sea level oscillations in the Permian are quite frequent, each of the above-mentioned sequences marking a third order cycle, with a sequence set representing a super cycle in sea-level changes. Based on the present study and incorporated with the researches in other areas of South China, it seems desirable to arrange the 16 sequences into 2 mesosequences [23] . The sequence set Ss1 forms the upper part of the Late Carboniferous Mesosequence which has its lower boundary at the basal Huashibanian Stage (about equivalent to the base of Bashkirian), around 315 Ma [14] . The other three sequence sets (Ss2-Ss4) constitute the Permian Mesosequence (or the Yanghsing Sequence [19] ), which was formed during a 2nd-order global sea-level cycle and roughly corresponds to the Transpecos Supercycle recognized in the North America [24] . The lower boundary of this Permian Mesosequence is correlated to the eminent discontinuity between the Maping Formation and Liangshan Formation in shelf region, and is widely recognizable in South China, North China, as well as in other regions of the world [5,13,24,25] , and was previously taken as the lower boundary of Permian in China. In southern Guizhou, this boundary is clearly shown as paleokarst surfaces in carbonate platform areas (e.g. in Dushan), above which terrestrial sediments are developed with coal-seams. In the foreslope area south of Ziyun, it shows as an obvious submarine erosion surface, above which 40 120 m clastics are deposited as LST wedges. Further southward to the Nanpanjiang Basin, it becomes a continuity surface, above which a set of thick claystone and shale are developed with abundant ammonoides. Conodont successions in the Luodian section show that the basal boundary of this mesosequence is about 6 m below the FAD of Sweetognathodus whitei , being middle Artinskian in age [13] . The upper boundary of the mesosequence may be set at very late Changhsingian, slightly below the P/T boundary. During this 2nd-order sea-level cycle, the marine transgression reached its maximum at early Guadalupian. Within this Permian Mesosequence, three major transgressions should be particularly emphasized, all of which are marked by sudden development of thin bedded chert or siliceous shale, indicating the maximum flooding deposits for the sequence sets of Ss2 to Ss4 respectively. The first significant transgression occurs at the base of bed 46 (fig. 4), slightly below the FAD of Neostreptognathodus exculptus , and accompanied with an important faunal turnover. At this horizon, schwagerinid fusulinids declined dramatically, and were replaced by Pamirina . In conodonts, Sweetognathodus was replaced by Neostreptognathodus, Pseudosweetognathodus and Mesogondolella. The second transgression happens at the base of bed 64 (fig. 5), about 4 m below the FAD of reliable Jinogondolella nankingensis . Here, turnover is also manifested clearly in both fusulinids and conodonts [4,19,20] . The third shows up distinctively at the bed 72-1, close to the base of Jinogondolella postbitteri zone. At this horizon, a profound change in fauna took place. More than 70% and up to 94% conodonts [19,20] , and 94% ammonoids [26] in the Guadalupian became extinct or were replaced by new forms. This event has been called the “End-Guadalupian Extinction” [26,27] and is regarded as the first episode of the Late Permian mass extinction [15,27] . It is important to notice that the three transgression events are all closely related to series boundaries. The first significant transgression is in accord with the base of Kungurian and would possibly serve as a boundary to split the Cisuralian into two subseries or independent series [5,6,13] . The second one is quite close to the base of Guadalupian and the third one to the base of Lopingian. Considering the facts that the first appearance of a given fossil species may be influenced considerably by facies and depositional environments, and its first appearance in a particular area may not always represent its true FAD in evolutionary lineage, it would be more practical and preferable to define the boundary of a biochronozone at the FFS or MFS nearest to the first appearance of the fossil species. Theoretically, a major transgression would provide the best opportunity for a new fauna or species to spread and colonize. And practically it has widely been noticed that the sudden occurrence of a fresh fauna is often accompanied by a new transgression. The advantages to define the boundary of a bio-chronozone or stages at the MFS are that this position is easy to recognize and the deposition has widest distribution in space, and therefore is desirable for correlation over broad regions. Therefore, the key surfaces in sequence can be used as important references in defining bio-chronozones and stages. The aforementioned three transgression events have great potential in Permian stratigraphic correlation across continents, and can be used as markers to fine-tune the stage and series ...

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... marine Permian is well developed in southern Guizhou and has been studied extensively both in stratigraphy and sedimentology. In the past years, however, most of the studies concentrated on shallow-water facies, mainly from the angle of litho- and bio-stratigraphy. As far as the Permian deep-water facies in southern Guizhou is concerned, emphasis has mostly focused on the establishment of the biostratigraphic successions [1 4] . This paper will focus on the sequence stratigraphy of the slope facies, mainly based on the section at Nashui of Luodian County. This has been regarded as one of the most important sections for the establishment of complete marine Permian chronostratigraphic framework in South China, and has the potential to establish the correlation between shallow- and deep-water facies, as well as the chronostratigraphic correlation between the Tethys and other regions [5,6] . Southern Guizhou is situated in southwestern part of the Yangtze Plate. During the Permian, most of the region was on the continental shelf and predominated by carbonate platform environments [5,7,8] . Studies show that there exists a reef belt in southern Guizhou [1,7,8] , which goes approximately in a NE-SW direction, extending from Xinyi to Ceheng, Ziyun and Luodian, then southeastward into Guangxi Zhuang Autonomous Region (fig. 1). To the north of the belt is a vast area where the Permian is characterized by shallow water deposits, consisting typically of light- colored carbonates rich in benthic fossils such as rugosals, brachiopods and fusulinids. Along the reef belt, the Permian is characterized by sponge-algal reefs or build-ups, as well as thick-bedded grainstone, oolite and bioclastic limestones, yielding prolific benthos. In the area just south of the reef belt, is a platform foreslope belt, in which the deposits are chiefly made up of dark-colored carbonates, intercalated with shale and chert-banded limestone. Lime breccias of slump origin, carbonate turbidites and debris flow deposits are quite common, often associated with argillaceous cherts. In this belt, macrofossils are relatively rare. Fusulinids are abundant, but largely in the gravity flow deposits, while conodonts are well documented in all the rocks. Further south of the belt is the Nanpanjiang Basin, where the Permian is mainly composed of shale, siltstone and cherts. In places, slump limestone breccias and intraclastic marlite can be observed, but generally not as thick as in the foreslope belt, with gravels much smaller in diameter. From the spatial distribution of sedimentary facies it can be seen that during the Permian, southern Guizhou had formed a continental margin. From north to south, the depositional environments clearly changed from carbonate platform interior to rimmed platform margin and foreslope, then to deep-water basin. The Nashui section of Luodian is likely at a lower part of the foreslope to the basin margin, and was previously assigned to black facies area to distinguish it from the carbonate platform facies in the north, which is referred to as white facies area [1,2,7] . As to the nature of the Nanpanjiang Basin, opinions are divergent. As no evidence of oceanic and related deposits were found in the region, it was either regarded as an intraplatform basin [1,7] separated from the Yangtze plate in the Permian (fig. 2) and there might have only been a seaway between them without oceanic crusts. The Permian at Nashui of Luodian is largely made up of dark colored carbonates continued from the Carboniferous without notable unconformity. For its relative monotonous lithology, no accepted lithostratigraphic subdivisions have been proposed so far, except its lower middle part, which is named as the Nashui Formation [2] . In this paper, a new subdivision, the Naqing Formation, is suggested for the strata between the Maokou Formation (Guadalupian) and the Changxing Formation (Upper Lopingian). This formation is characterized by siliceous shale, claystone and thin bedded chert, intercalated with fine grained lithic sandstone, tuffaceous siltstone and siliceous wackstone in the upper, indicating an origin of deep water basin. Lithogically it is quite distinct from the equivalent Wujiaping Formation of platform carbonates and the Longtan Formation characterized by coal-bearing alternating facies. For the other parts of the Permian, neither the lithostratigraphic subdivisions proposed for the basin facies around Houchang-Shaiwa area nor those for the shallow platform facies in central and southern Guizhou are suitable for this area. We tentatively take the commonly used subdivision names in South China, such as the Maping, Qixia, Maokou and Changxing formations, to this area. In the Nashui section, macro-fossils are rare, but conodonts and fusulinids are prolific. According to the fossil zonation, the regional stages proposed for the Permian of South China [2,5] can be clearly recognized and well correlated with the international standards [6,13] with confidence (fig. 3). In the Nashui section, the Cisuralian (Lower Permian) is quite thick, and includes several formations (fig. 4). The Maping Formation extends from the Upper Carboniferous to Lower Permian, and is relatively uniform in lithology. Its upperpart (Zisongian Stage) is largely composed of limestones, occasionally with thin marlite and shale beds. Bioclastic wackstone and packstone of distal gravity flow origin have been recognized at several horizons. In this part, both fusulinids and conodonts are well documented, pointing to an age of Asselian to middle Artinskian (fig. 3). The Nashui Formation (upper Artinskian to lower Kungurian) has a relatively small thickness and is mainly distinguished by siliceous shale and argillaceous cherts, alternated with limestones. Its lower part, however, is predominated by thin bedded limestone with chert bands and was probably deposited under a starved and oxygen-deficiency condition caused by rapid sea-level rise. The Qixia Formation, which constitutes the major part of the Kungurian, is much thicker than the Nashui Formation and relatively monotonous, mainly consisting of limestones and rarely bearing siliciclastic and chert beds. The Guadalupian (Middle Permian) is characterized by limestone, intercalated with argillaceous cherts. Wackstone, packstone and lime-mudstone are common, bioclastic limestone and a few of grainstone beds can also be observed in places and are probably related with distal gravity flow deposits. In the Guadalupian, fusulinids and conodonts are prolific, but rarely ...

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Cisuralian (Early Permian) paleogeographic evolution of South China Block and sea-level changes: Implications for the global Artinskian Warming Event

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Mar 2023
PALAEOGEOGR PALAEOCL

The final phase of the Late Paleozoic Ice Age (LPIA) involved a paleoclimatic transition from an icehouse to a greenhouse world during the Cisuralian (Early Permian in traditional stratigraphic correlation frameworks), which was called the Artinskian Warming Event (AWE). Paleogeography is an important tool to investigate the landform response to global sea-level changes in deep time. Stratigraphic sections gathered from published literature were digitized and stored in the Geobiodiversity Database. These biochronologically constrained sedimentary successions are used to reconstruct the paleogeographic evolution of the South China Block (SCB) throughout the Cisuralian. Four consecutive paleogeographic maps are constructed based on the features of sedimentary successions, including the Asselian – Sakmarian, the early Artinskian, the late Artinskian, and the Kungurian time intervals. These maps of the SCB may contribute to the implementation of global paleogeographic schemes. A landmass index based on spatial analysis of different elements is established further to identify the paleogeographic evolution pattern of SCB and reflect the LPIA-driven global eustatic signals. It showed two small cyclic fluctuation episodes during Asselian-Sakmarian, and Kungurian, respectively, and this trend was disrupted by a significant sea-level drop during early-middle Artinskian, which was comparable to sedimentary basins at different latitudes. The AWE and its associated marine transgression occurred no later than the late Artinskian according to rigorous biostratigraphic constraint. Large sea-level rise recorded in the Liangshan Member and Chihsia Formation is hypothesized to be the result of AWE climate change, which is regulated by the dynamic subsidence of the SCB and global concentrated volcanic eruptions since Artinskian.

Cisuralian (Early Permian) paleogeographic evolution of South China Block and sea-level changes: Implications for the global Artinskian Warming Event

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Jan 2023
PALAEOGEOGR PALAEOCL

Stratigraphy of the Guadalupian (Permian) siliceous deposits from central Guizhou of South China: Regional correlations with implications for carbonate productivity during the Middle Permian biocrisis

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Mar 2022
EARTH-SCI REV

In comparison with the amount of study undertaken on the end-Permian mass extinction, the preceding Guadalupian mass extinction has received little investigation, even though it marks a significant biotic turnover associated with global environmental changes. During the earlier event, reef carbonate production shut down and was replaced by siliceous, mud-rich deposits (SRDs) in South China. However, changes in carbonate platform productivity during this epoch remain to be clarified. This paper presents sedimentological and conodont biostratigraphic investigations on the Guadalupian SRDs developed on the Yangtze Carbonate Platform (YCP) in central Guizhou. The findings are viewed in the context of Guadalupian sequence correlation of South China successions, which shows that the integrity of the YCP failed to match the platform tectonic evolution. The platform evolution saw the onset of major intra-platform depressions and the gradual onlap by SRDs along the platform margin. Stratigraphic correlation reveals that the platform experienced three phases of onlap by SRDs during the early Roadian, the late Wordian and the late Capitanian upwards. Platform carbonates re-expanded their extent following the first two phases, but not during the final phase. An evolutionary model is proposed for the Guadalupian carbonate platform, which follows the contemporaneous eustatic sea-level fluctuations. The partial drowning observed within the platform interior and increasing retreat along the platform margin could suggest an insufficient carbonate sediment supply shedding from the platform top during the Guadalupian. The variation in carbonate productivity raises our attention to the change in shallow-water carbonate factories, which is closely related to the fortunes of carbonate-secreting biota and environmental factors impacting the carbonate platform producers during the Guadalupian.

Integrative timescale for the Lopingian (Late Permian): A review and update from Shangsi, South China

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Nov 2018
EARTH-SCI REV

The Lopingian is the uppermost series of the Paleozoic and it is bracketed by two major biological events, including the pre-Lopingian crisis and the end-Permian mass extinction (EPME). A high resolution temporal framework is essential to understand the patterns and causes of the extinction. Lopingian strata of South China have been intensively studied because three GSSPs have been defined in the region. Based on the review and updates to data from the Shangsi section as well as correlation with the Meishan section, the time framework for the Lopingian is revised, including biostratigraphy, chemostratigraphy, magnetostratigraphy, cyclostratigraphy and geochronology. The temporal framework is constrained by both precise geochronologic data and a high resolution conodont succession, and provides the possibility that the current high resolution marine international standard can also be applied to nonmarine strata by means of geochronology, magnetostratigraphy and cyclostratigraphy. The entire Lopingian high resolution conodont succession is for the first time, since the Lopingian Series was adopted as the international standard, recognized at a single section in South China and the succession correlates very well with the Lopingian GSSP sections at Penglaitan and Meishan. The Permian-Triassic boundary (PTB) of the Shangsi section is constrained to the basal 6 cm interval of Bed 28b in view of ammonoids, bivalves, conodonts, U-Pb ages and the EPME. The mass extinction interval is between Bed 27 and lower Bed 28a according to the EPME pattern at the Shangsi section, and the alternative interval between extinct Permian species and new Triassic species is from upper Bed 28a to lower Bed 28b. Unitary Association (UA) analysis of Lopingian conodonts reveals 15 unitary association zones (UAZs) based on seven important Lopingian sections of South China. Most of the UAZs correlate well with the standard biozonation, except for UAZ 3 to UAZ 5 and UAZ 12. The correspondence between UAZs and standard conodont biozones at the Shangsi section provides a practical example to understand controls on conodont UAZ determination. The Lopingian conodont succession is temporally calibrated by geochronologic ages, identified 405-kyr eccentricity cycles, and a Monte Carlo analysis at the Shangsi and Meishan sections. Updated ages for the base of the Lopingian and base of the Changhsingian are provided.

Guadalupian–Lopingian conodont and carbon isotope stratigraphies of a deep chert sequence in Japan

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Full-text available

Jun 2014
PALAEOGEOGR PALAEOCL

To improve international stratigraphic correlation of the Lower Guadalupian–Lower Lopingian (Permian), we examined the stratigraphies of conodonts and organic carbon isotopes from pelagic chert sequences in the Gujo-hachiman section, Gifu, southwest Japan. Age-diagnostic conodonts, such as Jinogondolella nankingensis and Jinogondolella shannoni were found in the study section. The conodont stratigraphy in the Gujo-hachiman section was correlated with those in South China and West Texas, USA, to date the study section. From these correlations, it was found that the study section was from the upper Roadian (Lower Guadalupian) through Wuchiapingian (Lower Lopingian). Kerogen δ13C values were relatively high, around -29.0‰ in the upper Roadian–Wordian (Middle Guadalupian), decreasing over time to -29.4‰. A negative–positive swing in δ13C values of around 1‰ magnitude was recognized in the middle Capitanian (Upper Guadalupian). A similar negative–positive swing was also found in the Guadalupian–Lopingian (G–L) transitional zone in the Gujo-hachiman section, and is comparable to the isotopic change around the G–L boundary in the Penglaitan section, South China. Subsequently, δ13C values decreased to values below -30.0‰ above the G–L transitional zone, i.e., at the lower Wuchiapingian. Overall, δ13C values decreased from the lower Capitanian to the lower Wuchiapingian by over 1.4‰. A gradual increase in the δ13C values followed this long-term negative trend. These δ13C trends in the Gujo-hachiman section are comparable with time-equivalent δ13C records in different sections, suggesting that they record first-order variations in atmospheric δ13C. The high δ13C values during the upper Roadian–Wordian interval could reflect high primary productivity in the surface water of the pelagic Panthalassa Ocean, and imply global cooling. In contrast, the negative δ13C shift during the Capitanian–Wuchiapingian interval implies global warming.

Report of the Chinese, Iranian, Italian working group: The Permian-Triassic boundary sections of Julfa and Zal revisited

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Sep 2013

Evaluation of the combined risk of sea level rise, land subsidence, and storm surges on the coastal areas of Shanghai, China

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CLIMATIC CHANGE

Shanghai is a low-lying city (3–4 m elevation) surrounded on three sides by the East China Sea, the Yangtze River Estuary, and Hangzhou Bay. With a history of rapid changes in sea level and land subsidence, Shanghai is often plagued by extreme typhoon storm surges. The interaction of sea level rise, land subsidence, and storm surges may lead to more complex, variable, and abrupt disasters. In this paper, we used MIKE 21 models to simulate the combined effect of this disaster chain in Shanghai. Projections indicate that the sea level will rise 86.6 mm, 185.6 mm, and 433.1 mm by 2030, 2050, and 2100, respectively. Anthropogenic subsidence is a serious problem. The maximum annual subsidence rate is 24.12 mm/year. By 2100, half of Shanghai is projected to be flooded, and 46 % of the seawalls and levees are projected to be overtopped. The risk of flooding is closely related to the impact of land subsidence on the height of existing seawalls and levees. Land subsidence increases the need for flood control measures in Shanghai.

The drivers of risk to water security in Shanghai

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Apr 2012
REG ENVIRON CHANGE

Big cities are often said to have big water problems, and Shanghai is no exception. In this paper, we examine and compare the influence of the major factors that give rise to the risk of water insecurity in Shanghai. There is an extensive and diverse literature on these issues, dealt with in isolation, and here, we provide a synthesis of the literature, together with our own assessments and calculations, to assess what are the risks to Shanghai’s water supply and what is our degree of confidence in this assessment. We describe the systems that supply water to the city, and past and future changes in the systems, including changes in the glaciers that supply some water to the river, changes in climate, changes in land use, the construction of dams, and water diversions. We show how, at the same time as Shanghai is increasing its dependence on the Yangtze river, water diversions and sea level rise are increasing the risk that this water will be too saline to consume at certain times of the year. This analysis suggests that most of the major drivers of the risk to water security in Shanghai are within the power of environmental managers to control.

Sequence-stratigraphic frameworks and their palaeogeographic patterns for the Permian Lopingian of the Dianqiangui Basin and its adjacent areas of Southwestern China

Article

Jun 2007
SCI CHINA SER D

The Permian Lopingian in the Dianqiangui Basin and its adjacent areas is marked by the coal measures of the Wuchiapingian and the carbonate strata of the Changhsingian stages. For the Lopingian of the Dianqiangui Basin and its adjacent areas, the diversity of sedimentary facies and the obviousness of facies change provide an advantaged condition on a study of sequence stratigraphy. Approximately, the Wuchiapingian stage constitutes a third-order sequence and the Changhsingian stage forms another. For the Wuchiapingian stage in the study area, coal-measures were developed on the attached platform and, in addition, a special coal-measure that is composed of both limestone beds and coal beds was also developed in the central part of some isolated platforms. Grain-bank grainstones and packstones were formed on the margin of the attached platform as well as in the windward part of isolated platforms. For the Changhsingian stage in the study area, open-platform limestones were formed on the attached platform, while sponge-reef limestones were developed both on the margin of the attached platform and on the isolated platforms. The Lopingian Series is a set of basin-facies muddy shales with interbeds of silicalites in the inter-platform basin, which appears a set of the large-thick coarse clastic strata of molasses covering direct the deep-water strata from the Devonian to the Permian Yangsingian in the Qinzhou-Fangcheng region in the southern part of the study area. All of these features indicate the complexity of temporal-spatial facies-changes. Sequence-stratigraphic frameworks could be established, which would illustrate two types of facies-changing surfaces and diachronisms in the stratigraphic records, based on the combination of both biostratigraphic and chronostratigraphic materials and the regularity reflected by temporal evolutionary succession of sediments as well as spatial distributional patterns of sedimentary facies. Ultimately, features of sedimentary succession and palaeogeographical evolution of the Permian Lopingian in the study area are revealed clearly in a series of the panel diagrams of sequence-stratigraphic frameworks and the outline maps showing the sedimentary-facies and palaeogeography. The Permian Lopingian formed by two third-order sequences differs from the stratigraphy of the same era characterized by the constant regression along Euramerica. Most specially, if the end-Guadalupian mass-extinction event is genetically related to a regressive event represented by the unconformity of the first episode of the Dongwu movement in the study area, the mass-extinction event at the turn from the Permian to the Triassic is genetically related to a rapid transgressive event reflected by the drowning unconformity in the study area. These phenomena might reveal a complex relationship between mass-extinction events and transgressive-regressive events.

Distribution characteristic and geological significance of rare earth elements in Lopingian mudstone of Permian, Panxian county, Guizhou province

Article

Jul 2011

In order to discuss the geochemical characteristic of REEs (rare earth elements) and their geological application, we measured the contents of rare earth elements, trace elements and minerals of 29 Lopingian (Late Permian) mudstone samples in Panxian county, carrying out ICP-MS and XRD analysis. The results show that the amount of REEs (185.56–729.46×10−6) is high. The ratios of w(LREE)/w(HREE) (6.84–13.86) and w(La)N/w(Yb)N (1.01–3.02) show clear differentiation of LREEs and HREEs. ΣREE has a significantly or critically positive correlation with lithophile elements Th, Nb, Ta, Ti, Ga, Sc, Cs, Zr, Hf, Sr, Be and chalcophile element Zn, a critically negative correlation with siderophile element Fe and a slightly positive correlation with illite, illite smectite mixed layers and siderite. REEs originate mainly from terrigenous minerals, in an inorganic phase. Source rocks of our samples consist of Emeishan basalt and a small part of sedimentary rocks, as suggested by the distribution patterns of REEs and w(∑REE)–w(La)/w(Yb) diagram. Moreover, abnormal surfaces near the sequence boundaries (SB2, SB3, SB4) are related with the boundaries, identified by geochemical characteristics of the REEs, such as ∑REE, w(LREE)/w(HREE), Eu/Eu∗ and Ceanom.

Cisuralian (Lower Permian) sequence successions and depositional characters at Nashui of Luodian County, southern Guizhou. Fossils mainly shown at the positions of their first appearances (FAD).

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