Your search keyword '"Lehrmann, Daniel J."' showing total 14 results

1. The role of carbonate factories and sea water chemistry on basin‐wide ramp to high‐relief carbonate platform evolution: Triassic, Nanpanjiang Basin, South China.

Author

Lehrmann, Daniel J., Stepchinski, Leanne M., Wolf, Hannah E., Li, Liangzi, Li, Xiaowei, Minzoni, Marcello, Yu, Meiyi, and Payne, Jonathan L.

Subjects

SEAWATER, WATER chemistry, CARBONATES, HYPOXEMIA, FACTORIES

Abstract

The end‐Permian extinction and its aftermath altered carbonate factories globally for millions of years, but its impact on platform geometries remains poorly understood. Here, the evolution in architecture and composition of two exceptionally exposed platforms in the Nanpanjiang Basin are constrained and compared with geochemical proxies to evaluate controls on platform geometries. Geochemical proxies indicate elevated siliciclastic and nutrient fluxes in the basal Triassic, at the Induan—Olenekian boundary and in the uppermost Olenekian. Cerium/Ce* shifts from high Ce/Ce* values and a lack of Ce anomaly indicating anoxia during the Lower Triassic to a negative Ce anomaly indicating oxygenation in the latest Olenekian and Anisian. Uranium and Mo depletion represents widespread anoxia in the world's oceans in the Early Triassic with progressive oxygenation in the Anisian. Carbonate factories shifted from skeletal in the Late Permian to abiotic and microbial in the Early Triassic before returning to skeletal systems in the Middle Triassic, Anisian coincident with declining anoxia. Margin facies shifted to oolitic grainstone in the Early Triassic with development of giant ooids and extensive marine cements. Anisian margins, in contrast, are boundstone with a diverse skeletal component. The shift in platform architecture from ramp to steep, high‐relief, flat‐topped profiles is decoupled from carbonate compositions having occurred in the Olenekian prior to the onset of basin oxygenation and biotic stabilisation of the margins. A basin‐wide synchronous shift from ramp to high‐relief platforms points to a combination of high subsidence rate and basin starvation coupled with high rates of abiotic and microbial carbonate accumulation and marine cement stabilisation of oolitic margins as the primary causes for margin up‐building. High sea water carbonate saturation resulting from a lack of skeletal sinks for precipitation, and basin anoxia promoting an expanded depth of carbonate supersaturation, probably contributed to marine cement stabilisation of margins that stimulated the shift from ramp to high‐relief platform architecture. [ABSTRACT FROM AUTHOR]

Published

2022

2. Magmatic activities and their impacts on oil/gas formation in the southwestern Ordos Basin, Central China.

Author

Li, Rongxi, Liu, Futian, Li, Sanzhong, Xi, Shengli, and Lehrmann, Daniel J.

Subjects

PETROLEUM prospecting, NATURAL gas prospecting, OIL well drilling, FOSSIL fuels, GEOLOGICAL basins

Abstract

The southwestern area of the Ordos Basin, China, contains good oil/gas systems, similar to the main basin. However, no oil/gas reserves have been found because some magmatic rocks with different occurrences developed in the region, it resulted in the suspension of oil/gas exploration in the 1980s. By means of integrated research based on field investigation, geophysical interpretation, and data of drilling wells, this paper indicates that magmatic activities in the southwestern Ordos Basin display different properties over multiple periods. The Proterozoic and Palaeozoic magmatic rocks are mainly distributed as a large batholith in the Qinling Orogen, and the Qilian Orogen around the southwestern margin of the Ordos Basin. These Proterozoic and Paleozoic plutons have no effect on hydrocarbon source rocks and oil/gas generation in the Ordos Basin. However, the Mesozoic magmatic activities developed within the basin have obvious effects on oil/gas generation. Three kinds of exploration regions were selected within the southwestern Ordos Basin according to the distribution of hydrocarbon source and magmatic rocks as well as the thermal degree: (a) the marginal area of the basin, (b) the region of the Longmen Uplift distributed with concealed magmatic rocks within the basin, and (c) the region within the basin far away from concealed magmatic rocks. Three sets of gas source rocks, that is, the Upper Proterozoic algal dolostone, the Middle Ordovician dark shale, the Upper Paleozoic black mudstone of coal system, and one set of oil source rocks of the Upper Triassic lacustrine black mudstone and oil shale, are exposed in outcrops near the margin of the basin. They all display a low thermal degree with vitrinite reflectance (Ro) below 1.3%, and they do not contribute to oil/gas accumulation because of earlier tectonic uplift. The gas source rocks and oil source rocks, which occur within the basin area of the Longmen Uplift, where the concealed magmatic rocks, display an abnormal thermal degree of over maturation with Ro over 3.4% and underwent dry gas generation because of heating from magmatic activity, and they have gas exploration potential. The source rocks distributed within the basin area away from concealed magmatic rocks display a normal thermal degree and oil/gas generation. The Ro of the Upper Triassic oil source rock is 1.0–1.6%, which is under the thermal maturity stage of liquid oil generation, whereas that of the Upper Paleozoic gas source rocks is 2.0–2.5% under the thermal maturity stage of gas generation. Measured Ro and burial depth of source rocks in the region show a linear relationship, which indicate that source rocks experienced thermal evolution and oil/gas generation under the normal burial thermal condition rather than the magmatic activity. This region has the most potential for both oil and gas exploration. [ABSTRACT FROM AUTHOR]

Published

2018

3. Unraveling overprinted formation mechanisms of massive dolostone in the Lower Triassic sequence of an isolated carbonate platform in Nanpanjiang Basin, south China.

Author

Li, Xiaowei, Lehrmann, Daniel J., Luczaj, John, Kelley, Brian M., Cantrell, Dave L., Yu, Meiyi, Ferrill, Nathaniel Ledbetter, and Payne, Jonathan L.

Subjects

*DOLOMITE, *FLUID inclusions, *CARBONATES, *BRECCIA, *HIGH temperatures, *PETROLOGY, *GEOCHEMISTRY

Abstract

Massive dolomitization is common in carbonate platforms but determining the causes of dolomitization remains challenging. A particular difficulty lies in identifying cases where petrographic and geochemical attributes of dolostone related to one mechanism could be obscured by a later, different one. To better understand whether traditional approaches are sufficient to unravel the origins of dolostone resulting from successive, different mechanisms, this study investigates the formation mechanism(s) of dolostone along a platform-to-basin transect of a Permian-Triassic isolated platform in the Nanpanjiang Basin. The dolostone in the Lower Triassic succession comprises three dolomite phases that can be distinguished through field relationships, petrography, 87Sr/86Sr ratios, and microthermometry. Dolomite type 1 formed due to the reflux of platform-top evaporated seawater that flowed through the platform interior in the Early Triassic. Dolomite types 2 and 3 are interpreted to have formed at elevated temperatures during or after Late Triassic platform burial and to have played a secondary role in forming the dolostone. The dolomitizing fluids that resulted in the formation of dolomite types 2 and 3 were derived from Early Triassic seawater-like fluid that was expelled from the Lower Triassic basinal carbonate sediments and moved updip to the platform interior. Dolomitized clasts in partially or non-dolomitized slope breccias demonstrate pre-burial timing of dolomite type 1, and distinguish the earlier dolomitization from later, post-burial dolomitization represented by dolomite types 2 and 3. Dolomite type 1 retains its Early Triassic seawater δ13C and 87Sr/86Sr signatures, whereas overlapping geochemical fields of the three types of dolomite (trace element concentration, δ18O) imply that burial dolomitizing fluids locally reset the geochemistry of dolomite type 1. This finding suggests that the same dolomite archive may retain well-preserved or altered data depending on the specific geochemical proxy and that identifying individual dolomitization mechanisms using geochemical proxies is possible only in some cases. • The studied Lower Triassic succession is extensively dolomitized in south China. • The succession results from two mechanisms: reflux and burial dolomitization. • Dolomitized clasts in slope breccia help distinguish pre-burial timing of dolomite. • Burial dolomitizing fluids locally reset the geochemistry of early reflux dolomite. [ABSTRACT FROM AUTHOR]

Published

2022

4. Calcium isotope constraints on the end-Permian mass extinction.

Author

Payne, Jonathan L., Turchyn, Alexandra V., Paytan, Adina, DePaolo, Donald J., Lehrmann, Daniel J., Meiyi Yu, and Jiayong Wei

Subjects

PERMIANS, MASS extinctions, CARBONATE minerals, CARBON isotopes, GEOMAGNETIC secular variation

Abstract

The end-Permian mass extinction horizon is marked by an abrupt shift in style of carbonate sedimentation and a negative excursion in the carbon isotope (δ13C) composition of carbonate minerals. Several extinction scenarios consistent with these observations have been put forward. Secular variation in the calcium isotope (δ44/40Ca) composition of marine sediments provides a tool for distinguishing among these possibilities and thereby constraining the causes of mass extinction. Here we report δ44/40Ca across the Permian-Triassic boundary from marine limestone in south China. The δ44/40Ca exhibits a transient negative excursion of ∼0.3%o over a few hundred thousand years or less, which we interpret to reflect a change in the global δ44/40Ca composition of seawater. CO2-driven ocean acidification best explains the coincidence of the δ44/40Ca excursion with negative excursions in the δ13C of carbonates and organic matter and the preferential extinction of heavily calcified marine animals. Calcium isotope constraints on carbon cycle calculations suggest that the average δ13C of CO2 released was heavier than -28%o and more likely near -15%o; these values indicate a source containing substantial amounts of mantle-or carbonate-derived carbon. Collectively, the results point toward Siberian Trap volcanism as the trigger of mass extinction. [ABSTRACT FROM AUTHOR]

Published

2010

5. Record of the end-Permian extinction and Triassic biotic recovery in the Chongzuo-Pingguo platform, southern Nanpanjiang basin, Guangxi, south China

Author

Lehrmann, Daniel J., Payne, Jonathan L., Pei, Donghong, Enos, Paul, Druke, Dominic, Steffen, Kelley, Zhang, Jinan, Wei, Jiayong, Orchard, Michael J., and Ellwood, Brooks

Subjects

*BIOTIC communities, *SEDIMENTATION & deposition, *PERMIANS

Abstract

Abstract: The Chongzuo-Pingguo platform is a vast isolated platform, 180 km across, in the southern part of the Nanpanjiang basin. The end-Permian extinction is recorded in conformable sections in the northern part of the platform (Pingguo area). Upper Permian skeletal packstone contains diverse open-marine fossils including Nankinella and Sphaerulina. It is overlain by a 4.6 m thick horizon of calcimicrobial framestone constructed by globular calcified microbial framework similar to Renalcis. The PTB event horizon is interpreted to occur at the top of the packstone, coincident with the abrupt change to calcimicrobial framestone lacking Permian macrofossils. The transition from Hindeodus latidentatus to H. parvus occurs 1 m above the base of the calcimicrobial framestone, marking the conformable biostratigraphic boundary. During the Early Triassic the platform developed as a low-relief bank rimmed with oolite shoals but was bordered by a high-relief, fault-controlled escarpment along its southern margin. Platform interior facies of the Majiaoling and Beisi formations are 900 m thick and consist of thin-bedded lime mudstone, oolite, and dolostone with restricted marine biota in four shallowing-upward packages that define depositional sequences. In the Chongzuo area the platform was terminated at the end of the Early Triassic by burial with up to 1600 m of felsic pyroclastic volcanics and lava flows. Transgression and shallow-marine carbonate sedimentation resumed early in the Middle Triassic followed by drowning in the Bithynian as indicated by a shift to deep-marine carbonate and clastic deposition. In the Pingguo area volcanic deposits are much thinner and only briefly interrupted carbonate accumulation. Here the platform interior drowned during a major back step early in the Middle Triassic (Anisian, Bithynian). Smaller pinnacle platforms of the Guohua Fm., up to 1700 m thick, continued to accumulate above the Early Triassic platform margin and were eventually drowned by the Late Pelsonian. In the Anisian, the pinnacle platforms shifted to sharply defined, reef-rimmed margins with Tubiphytes reefs. The shift coincides with accelerated metazoan biotic recovery in the Anisian. However, the reefs lack metazoan frameworks and are composed almost entirely of Tubiphytes reinforced by large volumes of marine cement. These observations indicate that controls beyond the recovery of framework-building metazoans governed the re-establishment platform-margin reefs in the Middle Triassic. [Copyright &y& Elsevier]

Published

2007

6. Timing of recovery from the end-Permian extinction: Geochronologic and bostratigraphic constraints from south China.

Author

Lehrmann, Daniel J., Ramezani, Jahandar, Bowring, Samuel A., Martin, MArk W., Montgomery, Paul, Enos, Paul, Payne, Jonathan L., Orchard, Michael J., Hongmei, Wang, and Jiayong, Wei

Subjects

*GEOLOGICAL time scales, *CONODONTS, *PERMIANS, *TRIASSIC stratigraphic geology, *BIOLOGICAL extinction, *ZIRCON, *ANDOSOLS, *STRATIGRAPHIC correlation

Abstract

Four volcanic-ash beds bracket the Early-Middle Triassic boundary, as defined by conodont biostratigraphy, in a stratigraphic section in south China. High-precision U-Pb dates of single zircons allow us to place the Early to Middle Triassic (Olenekian-Anisian) boundary at 247.2 Ma. Magnetic-reversal stratigraphy allows global correlation. The new dates constrain the Early Triassic interval characterized by delayed biotic recovery and carbon-cycle instability to ~5 m.y. This time constraint must be considered in any model for the end-Permian extinction and subsequent recovery. [ABSTRACT FROM AUTHOR]

Published

2006

7. Milankovitch climatic signals in Lower Triassic (Olenekian) peritidal carbonate successions, Nanpanjiang Basin, South China

Author

Yang, Wan and Lehrmann, Daniel J.

Subjects

*CLIMATOLOGY, *TRIASSIC stratigraphic geology, *SEDIMENTATION & deposition

Abstract

Meter-scale peritidal carbonate strata from an isolated platform in the Nanpanjiang Basin of South China were tested for the presence of periodic or quasi-periodic climatic signals. These signals provide information on factors controlling cyclic sedimentation in the equatorial eastern Tethys during the Early Triassic greenhouse period. Parasequences are composed of shallowing-upward successions of subtidal facies, including skeletal packstone and grainstone, calcimicrobial boundstone, and oolitic packstone and grainstone, intertidal laminated lutite and ribbon rock, and rare supratidal microbial laminite. Parasequence stacking patterns display three orders of cyclicity, suggesting hierarchical stratigraphic relationships. Gamma analysis of Kominz and Bond [Earth Planet. Sci. Lett. 48 (1990) 233–244] was used to estimate facies-dependent thickness–time conversion factors (i.e. γs), and to construct γ-tuned and γ-untuned time series for two stratigraphic sections. Spectra of these time series indicate the presence of quasi-periodic signals, with prominent short-eccentricity (94.9–131.2 kyr), short-obliquity (35.8 kyr), and long-precessional index (21.2 kyr) peaks, and minor long-eccentricity (412.9 kyr), long-obliquity (45.3 kyr), short-precessional index (17.7 kyr), and constructional-tone (9.7 kyr) peaks when calibrated on the γ-tuned spectra. Thus, Milankovitch climatic forcing probably greatly influenced sedimentation. The calibration indicates that the subtidal facies has a sedimentation rate of 24.6–30.7 cm/kyr and the intertidal–supratidal facies has a rate of 2.7–6.0 cm/kyr. The estimated duration of deposition of the two sections is 1139–1423 kyr, and corresponds to a stratigraphic completeness of 32–92%. The completeness is much greater than that of icehouse stratigraphic records. We speculate that variations in carbonate productivity and environmental conditions driven by Milankovitch climatic forcing, combined with low-amplitude sea-level fluctuations, were likely major controls on cyclic sedimentation. Furthermore, evolutional spectra of the two sections show that dominant Milankovitch climatic forcings varied from short-eccentricity, obliquity, to long-precessional index during the course of sedimentation. Some spectral differences between the two sections suggest variations in depositional/recording mechanisms of Milankovitch climatic signals between platform interior and windward platform margin. [Copyright &y& Elsevier]

Published

2003

8. Impact of differential tectonic subsidence on isolated carbonate-platform evolution: Triassic of the Nanpanjiang Basin, south China.

Author

Lehrmann, Daniel J., Pei Donghong, Enos, Paul, Minzoni, Marcello, Ellwood, Brooks B., Orchard, Michael J., Zhang Jiyan, Wei Jiayong, Dillett, Pete, Koenig, Jon, Steffen, Kelley, Druke, Dominic, Druke, Jordayna, Kessel, Benjamin, and Newkirk, Trent

Subjects

CARBONATE minerals, CARBONATES, GEOLOGICAL basins, STRATIGRAPHIC geology

Abstract

The Nanpanjiang Basin of south China contains four exceptionally well-exposed, isolated Triassic carbonate platforms. Detailed mapping of two-dimensional transects and description of stratigraphic sections allow the reconstruction of facies architecture, sequence stratigraphy, and evolution of the platforms. Biostratigraphy, magnetic-susceptibility profiles, and volcanic-ash horizons allow chronostratigraphic correlation and, thus, a basinwide evaluation of mechanisms controlling platform evolution. A comparison of platform architecture demonstrates that southerly platforms have substantially greater thickness, backstepping geometry, pinnacle development, and earlier drowning that resulted from greater tectonic subsidence proximal to a probable convergent margin along the southern perimeter of the basin. Felsic volcanics thicken southward and contributed to the termination of the southernmost platform, indicating the development of a volcanic arc along the southern margin of the South China tectonic block. The northernmost isolated platform had greater longevity and lesser accumulation and lacks backstepping and pinnacle phases of development. Basin-margin intertonguing relationships, or lack thereof, demonstrate that earlier siliciclastic influx into the basin to the south and concurrent starved-basin conditions to the north impacted the evolution of platform-margin geometries. [ABSTRACT FROM AUTHOR]

Published

2007

9. Triassic Foraminifera from the Great Bank of Guizhou, Nanpanjiang Basin, south China: taxonomic account, biostratigraphy, and implications for recovery from end-Permian mass extinction.

Author

Altıner, Demir, Payne, Jonathan L., Lehrmann, Daniel J., Özkan-Altıner, Sevinç, Kelley, Brian M., Summers, Mindi M., and Yu, Meiyi

Subjects

*MASS extinctions, *PERMIAN-Triassic boundary, *FORAMINIFERA, *BIOSTRATIGRAPHY, *OCEAN bottom, *CHEMOSTRATIGRAPHY, *CARBON isotopes

Abstract

Foraminifera are important components of tropical marine benthic ecosystems and their recovery pattern from the end-Permian mass extinction can yield insights into the Mesozoic history of this group. Here we report the calcareous and agglutinated foraminifera recovered from five measured stratigraphic sections on the Great Bank of Guizhou, an uppermost Permian to Upper Triassic isolated carbonate platform in the Nanpanjiang Basin, south China. The material contains >100 Triassic species, including three that are newly described (Arenovidalina weii n. sp., Meandrospira? enosi n. sp., and Spinoendotebanella lehrmanni n. gen., n. sp.), ranging from Griesbachian (Induan) to Cordevolian (Carnian) age. The species belong to the classes Miliolata, Textulariata, Fusulinata, Nodosariata, and to an unknown class housing all aragonitic forms of the orders Involutinida and Robertinida. Based on previously established conodont zones and carbon isotope chemostratigraphy, the Griesbachian (early Induan) through Illyrian (late Anisian) interval has been subdivided into 12 foraminiferal zones and two unnamed intervals devoid of foraminifera. Following the extinction at the Permian-Triassic boundary, habitable ecological niches of Griesbachian age were invaded by disaster taxa that subsequently became extinct during the Dienerian (late Induan) and left no younger descendants. The disaster taxa were replaced by Lazarus taxa with Permian origins, which were then decimated by the Smithian-Spathian (mid-Olenekian) boundary crisis. The tempo of recovery appears to have been modulated by environmental changes during the Griesbachian through Smithian that involved both climate change and expansion of anoxic ocean bottom waters. Uninterrupted and lasting recovery of benthic foraminifera did not begin until the Spathian. UUID: http://zoobank.org/2a6e9061-b163-402a-9098-8765a80576b3 [ABSTRACT FROM AUTHOR]

Published

2021

10. Implications of giant ooids for the carbonate chemistry of Early Triassic seawater.

Author

Li, Xiaowei, Trower, Elizabeth J., Lehrmann, Daniel J., Minzoni, Marcello, Kelley, Brian M., Schaal, Ellen K., Altiner, Demir, Meiyi Yu, and Payne, Jonathan L.

Subjects

*LIMESTONE, *SEAWATER, *CARBONATE minerals, *CARBONATES, *MASS extinctions, *ARAGONITE, *OCEAN

Abstract

Lower Triassic limestones contain giant ooids (>2 mm) along with other precipitated carbonate textures more typical of Precambrian strata. These features appear to have resulted from changes in seawater chemistry associated with the end-Permian mass extinction, but quantifying the carbonate chemistry of Early Triassic seawater has remained challenging. To constrain seawater carbonate saturation state, dissolved inorganic carbon, alkalinity, and pH, we applied a physicochemical model of ooid formation constrained by new size data on Lower Triassic ooids from south China, finding that the Triassic giant ooids require a higher carbonate saturation state than typifies modern sites of ooid formation. Model calculations indicate that Early Triassic oceans were at least seven times supersaturated with respect to aragonite and calcite. When combined with independent constraints on atmospheric pCO2 and oceanic [Ca2+], these findings require that Early Triassic oceans had more than twice the modern levels of dissolved inorganic carbon and alkalinity and a pH near 7.6. Such conditions may have played a role in inhibiting the recovery of skeletal animals and algae during Early Triassic time. [ABSTRACT FROM AUTHOR]

Published

2021

11. Factors controlling carbonate platform asymmetry: Preliminary results from the Great Bank of Guizhou, an isolated Permian–Triassic Platform in the Nanpanjiang Basin, south China

Author

Li, Xiaowei, Yu, Meiyi, Lehrmann, Daniel J., Payne, Jonathan L., Kelley, Brian M., and Minzoni, Marcello

Subjects

*CARBONATE analysis, *ASYMMETRY (Chemistry), *PERMIAN stratigraphic geology, *TRIASSIC stratigraphic geology, *ECOLOGICAL disturbances, *MORPHOTECTONICS, *GEOLOGICAL basins

Abstract

Abstract: A well-exposed isolated carbonate platform, the Great Bank of Guizhou, in the Nanpanjiang Basin of south China, developed from the latest Permian to the earliest Late Triassic. Platform strata are dissected by a faulted syncline exposing a complete cross section through the interior, margins and flanks, enabling a detailed assessment of depositional controls. Previous studies portrayed the platform as having a relatively symmetrical architecture even though much of the former work was focused on the platform interior and northern margin–basin transition. Our research reveals five aspects of the southern margin facies and stratigraphy that are significantly different from those of the northern margin: (1) subaerial exposure and unconformity developed on top of the Upper Permian sponge boundstone and in the overlying Lower Triassic strata; (2) Permian and Triassic clasts chaotically admixed within Early Triassic breccias; (3) Lower Triassic strata remarkably thinner on the southern margin; (4) a much narrower Tubiphytes reef facies preserved along the southern margin in the Middle Triassic; and (5) large scallop shaped reentrants at the southern margin evident in satellite images. Three end-member models may explain the asymmetry: (1) antecedent topography of the underlying Upper Permian reef-rimmed margin coupled with eustatic sea level fluctuation; (2) differential tectonic uplift; and (3) large-scale submarine collapse of the platform margin. Subaerial exposure and admixing of Permian and Triassic clasts observed at Yungan section is best explained by the tectonic uplift model. However, the submarine collapse model also explains several of the observations if it is associated with uplift(s) or sea level fall(s). Submarine collapse is supported by large concave erosional reentrants (scallops) visible in satellite images. Taken together, our observations suggest that a combination of tectonic uplift and margin collapse contributed to platform asymmetry. Further work promises to further constrain the details and timing of processes that contributed to the asymmetry. [Copyright &y& Elsevier]

Published

2012

12. Interactions between sediment production and transport in the geometry of carbonate platforms: Insights from forward modeling of the Great Bank of Guizhou (Early to Middle Triassic), south China.

Author

Li, Xiaowei, Falivene, Oriol, Minzoni, Marcello, Lehrmann, Daniel J., Reijmer, John J.G., Morsilli, Michele, Al-Ramadan, Khalid A.H., Yu, Meiyi, and Payne, Jonathan L.

Subjects

*CARBONATES, *SEDIMENTATION & deposition, *WATER depth, *INDUSTRIAL capacity, *GEOMETRY, *SEDIMENT transport, *PARAGENESIS

Abstract

Carbonate platforms grow through the precipitation, transport, and final deposition of carbonate sediment out of seawater. Quantifying the relative contributions of initial production versus subsequent transport in determining the growth rates and geometries of platforms remains a significant challenge. In this study, stratigraphic forward modeling is used to quantify the roles of sediment production, transport, and deposition during each growth stage of a Permian-Triassic carbonate platform with a complex growth history. Parameter optimization and sensitivity analysis show that, within the range of reasonable values, the morphology of the platform is most sensitive to sediment transport, moderately sensitive to maximum carbonate production rate, and least sensitive to the productivity-depth curve. The ramp-to-high relief, steep-sloped platform transition during Early Triassic time can be explained by any factor that limits sediment transport from shallow water areas of high production to the slope and basin. Reefs may play a role in limiting sediment transport on many platforms but other processes, such as early marine cementation or carbonate production along the slope, may be equally capable of yielding this shift in platform geometry. In this particular case, early lithification of ooid and skeletal shoals on the platform margin, perhaps facilitated by unusually high carbonate saturation state of seawater, may have inhibited sediment transport into the basin prior to the development of a reef on the platform margin. Later, Anisian progradation of the platform margin can be explained by the development of a slope factory rather than requiring increased sediment transport from the platform top. The development of an escarpment margin in the Ladinian is mainly influenced by accommodation in the slope profile created by antecedent Anisian topography. A general implication from the model results is that the growth of steep-sloped carbonate platforms lacking slope factories may often be limited by transport of sediment from the platform top to accommodation on the slope rather than by the intrinsic production capacity of the platform top factory. • High carbonate saturation can promote a ramp to steep-sloped platform transition. • Carbonate platform growth is limited by production-capacity and transport-capacity. • Carbonate platform geometry is more sensitive to transport than sediment production. [ABSTRACT FROM AUTHOR]

Published

2020

13. Facies selectivity of benthic invertebrates in a Permian/Triassic boundary microbialite succession: Implications for the "microbialite refuge" hypothesis.

Author

Foster WJ, Lehrmann DJ, Yu M, and Martindale RC

Subjects

Animals, China, Geologic Sediments analysis, Biodiversity, Fossils, Invertebrates classification

Abstract

Thrombolite and stromatolite habitats are becoming increasingly recognized as important refuges for invertebrates during Phanerozoic Oceanic Anoxic Events (OAEs); it is posited that oxygenic photosynthesis by cyanobacteria in these microbialites provided a refuge from anoxic conditions (i.e., the "microbialite refuge" hypothesis). Here, we test this hypothesis by investigating the distribution of ~34, 500 benthic invertebrate fossils found in ~100 samples from a microbialite succession that developed following the latest Permian mass extinction event on the Great Bank of Guizhou (South China), representing microbial (stromatolites and thrombolites) and non-microbial facies. The stromatolites were the least taxonomically diverse facies, and the thrombolites also recorded significantly lower diversities when compared to the non-microbial facies. Based on the distribution and ornamentation of the bioclasts within the thrombolites and stromatolites, the bioclasts are inferred to have been transported and concentrated in the non-microbial fabrics, that is, cavities around the microbial framework. Therefore, many of the identified metazoans from the post-extinction microbialites are not observed to have been living within a microbial mat. Furthermore, the lifestyle of many of the taxa identified from the microbialites was not suited for, or even amenable to, life within a benthic microbial mat. The high diversity of oxygen-dependent metazoans in the non-microbial facies on the Great Bank of Guizhou, and inferences from geochemical records, suggests that the microbialites and benthic communities developed in oxygenated environments, which disproves that the microbes were the source of the oxygenation. Instead, we posit that microbialite successions represent a taphonomic window for exceptional preservation of the biota, similar to a Konzentrat-Lagerstätte, which has allowed for diverse fossil assemblages to be preserved during intervals of poor preservation., (© 2019 John Wiley & Sons Ltd.)

Published

2019

14. Large perturbations of the carbon cycle during recovery from the end-permian extinction.

Author

Payne JL, Lehrmann DJ, Wei J, Orchard MJ, Schrag DP, and Knoll AH

Subjects

Animals, Calcification, Physiologic, Carbon metabolism, Carbon Isotopes analysis, China, Eukaryota, Invertebrates anatomy & histology, Methane analysis, Oxygen, Time, Biodiversity, Carbon analysis, Ecosystem, Fossils, Geologic Sediments chemistry

Abstract

High-resolution carbon isotope measurements of multiple stratigraphic sections in south China demonstrate that the pronounced carbon isotopic excursion at the Permian-Triassic boundary was not an isolated event but the first in a series of large fluctuations that continued throughout the Early Triassic before ending abruptly early in the Middle Triassic. The unusual behavior of the carbon cycle coincides with the delayed recovery from end-Permian extinction recorded by fossils, suggesting a direct relationship between Earth system function and biological rediversification in the aftermath of Earth's most devastating mass extinction.

Published

2004