Hostname: page-component-7bb8b95d7b-dvmhs Total loading time: 0 Render date: 2024-09-27T03:27:49.389Z Has data issue: true hasContentIssue false
  • English
  • Français

New SIMS U–Pb zircon age on the macroscopic multicellular eukaryotes from the early Mesoproterozoic Gaoyuzhuang Formation, North China

Published online by Cambridge University Press:  23 September 2024

Kai Chen Open the ORCID record for Kai Chen [Opens in a new window] ,
Chuan Yang ,
Lanyun Miao ,
Fangchen Zhao Open the ORCID record for Fangchen Zhao [Opens in a new window]  and
Maoyan Zhu Open the ORCID record for Maoyan Zhu [Opens in a new window]
Kai Chen
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing, China
Chuan Yang
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing, China College of Earth & Planetary Sciences, University of Chinese Academy of Sciences, Beijing, China
Lanyun Miao
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing, China
Fangchen Zhao
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing, China College of Earth & Planetary Sciences, University of Chinese Academy of Sciences, Beijing, China
Maoyan Zhu*
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing, China College of Earth & Planetary Sciences, University of Chinese Academy of Sciences, Beijing, China
*
Corresponding author: Maoyan Zhu; Email: myzhu@nigpas.ac.cn
Rights & Permissions [Opens in a new window]

Abstract

Decimetre-scale carbonaceous macrofossils from the Mesoproterozoic Gaoyuzhuang Formation in the Yanshan Range are known as the current oldest unambiguous evidence of macroscopic multicellular eukaryotes. Here, we reported a new SIMS zircon age of 1588.8 ± 6.5 Ma from a volcanic tuff in the Qianxi County of Hebei Province, about 11 m above the macrofossil’s horizon. This new age provides a direct age constraint on the macroscopic eukaryotic fossils from the Gaoyuzhuang Formation. It indicates that macroscopic life with the moderate diversity and certain morphological complexity had already evolved at the beginning of the Mesoproterozoic, and implies a possibility of discovering macroscopic eukaryotes in earlier rocks. This study also calls for a stratigraphic framework to integrate biological and environmental studies in different regions for a better understanding of the evolution of multicellular organisms and environmental change during this important period.

Keywords

SIMS U–Pb datecarbonaceous macrofossilsmulticellular eukaryotesGaoyuzhuangFormationMesoproterozoic
Type
Original Article
Information
Geological Magazine , First View , pp. 1 - 5
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

1. Introduction

The emergence of multicellular organisms is a critical milestone in the evolution of life on Earth (Bonner, Reference Bonner1998; Niklas and Newman, Reference Niklas and Newman2020). The current oldest unambiguous evidence of macroscopic multicellular eukaryotes is the decimetre-scale carbonaceous macrofossils from the Mesoproterozoic Gaoyuzhuang Formation in the Yanshan Range, North China (Zhu et al. Reference Zhu, Zhu, Knoll, Yin, Zhao, Sun, Qu, Shi and Liu2016; Chen et al. Reference Chen, Miao, Zhao and Zhu2023). These macrofossils display multiple regular morphologies (cuneate, linear, oblanceolate and tongue-shaped) and large dimensions up to several centi- to decimetres, exhibiting resemblances to some living macroalgae (Zhu et al. Reference Zhu, Zhu, Knoll, Yin, Zhao, Sun, Qu, Shi and Liu2016; Chen et al. Reference Chen, Miao, Zhao and Zhu2023). Their age has been approximately constrained to 1560 Ma–1580 Ma by zircon U–Pb ages from two outcrops in Yanqing, Beijing (Li et al. Reference Li, Zhu, Xiang, Wenbo, Songnian, Hongying, Jianzhen, Sheng and Fengjie2010) and Jizhou, Tianjin (Tian et al. Reference Tian, Zhang and Li2015, Reference Tian, Li and Zhang2020) which are about one hundred kilometres apart (Fig. 1(a)).

Figure 1. Geological setting of the sample. (a) Distribution of Proterozoic outcrops in the Yanshan Range showing the reported tuff locations. (b) Correlation of the horizons of reported zircon U–Pb ages and fossils at (1) Yanqing, (2) Jizhou and (3) Qianxi. (c) Outcrop photograph of the tuff bed (yellow arrow) in the section. (d) Macrofossils (red arrows) from Member 3 of the Gaoyuzhuang Formation in Qianxi, Hebei.

The lack of direct age constraint on these macrofossils hinders our understanding of the timing of the origin and early evolution of macroscopic eukaryotes. Macrofossils with regularly repeated forms were mainly found in Qianxi County of Hebei Province (Zhu et al. Reference Zhu, Zhu, Knoll, Yin, Zhao, Sun, Qu, Shi and Liu2016; Chen et al. Reference Chen, Miao, Zhao and Zhu2023), but the host sections lack relevant geochemical and geochronological studies of Gaoyuzhuang Member 3. Considering the variational facies of the Gaoyuzhuang Formation in the Yanshan Range (Liang and Jones, Reference Liang and Jones2021), direct age constraints for the macrofossil assemblages are necessary to understand the relationship between the origin of multicellular organisms and associated environmental conditions (Zhang et al. Reference Zhang, Zhu, Wood, Shi, Gao and Poulton2018).

Here, a new zircon age of a volcanic tuff several meters above the fossil horizon at the Qianxi section is reported. The precise SIMS U–Pb zircon age provides a direct age constraint for the important fossil assemblage.

2. Materials and methods

The Mesoproterozoic Gaoyuzhuang Formation is widely distributed in the Yanshan Range and is considered to be accumulated during a marine transgression (Tian and Zhai, Reference Tian and Zhai1996). Located between the sandstone of the Dahongyu Formation and the silty dolomite of the Yangzhuang Formation, the Gaoyuzhuang Formation is dominated by carbonate and is subdivided into four members (Tian and Zhai, Reference Tian and Zhai1996). Member 3 of the Gaoyuzhuang Formation constitutes a large portion of this rock unit, which is about 680 m thick in the type section at Northern Jizhou District, Tianjin Municipality, with the lower half dominated by medium to thick-bedded dolostones and the upper half dominated by dolomitic limestones. The dolomitic limestones bear small fossiliferous siliceous concretions (Shi et al. Reference Shi, Feng, Khan and Zhu2017) and molar-tooth structures (Mei and Tucker, Reference Mei and Tucker2011).

In the section at Qianxi County of Hebei Province, Member 3 is about 470 m thick, dominated by medium to thick-bedded dolostone and argillaceous dolostone, with subordinate siltstone and mudstone. The blade-like macrofossils were reported in muddy dolostone about 225 m above the bottom of this member (Zhu et al. Reference Zhu, Zhu, Knoll, Yin, Zhao, Sun, Qu, Shi and Liu2016; Chen et al. Reference Chen, Miao, Zhao and Zhu2023). Many smaller macrofossils have recently been discovered in the dolomitic mudstone about 435 m above the bottom (Chen et al. Reference Chen, Miao, Zhao and Zhu2023).

About 11 m above the upper macrofossil horizon (Fig. 1(b)), the sample QXHY-6 was obtained from a tuff bed at an outcrop ca. 800 m west of the urban district of Qianxi County (Fig. 1(a), 40° 07′ 50″ N, 118° 16′ 32″ E).

Zircon crystals were separated from ca. 5 kg sample (QXHY-6) by the conventional density and magnetic separation methods. Mounted in an epoxy disk with the reference zircons of Plešovice and Qinghu, the grains were then polished to section the crystals in half for analysis. All zircon crystals were documented with transmitted and reflected light photomicrographs and cathodoluminescence (CL) images to reveal their external and internal structures.

U, Th and Pb isotopes were measured using a CAMECA IMS 1280-HR at the Beijing Research Institute of Uranium Geology, following conventional methods (Li et al. Reference Li, Liu, Li, Guo and Chamberlain2009). The O2 primary beam, accelerated at ∼13 kV with an intensity of ca. 10 nA, was used to bombard the zircon surfaces, resulting in ellipsoidal analysis spots with sizes of about 20 μm × 30 μm, respectively. Analyses of the unknown grains were interspersed with those of the reference zircon at a ratio of 3:1.

The ratios of U–Th–Pb are determined relative to the reference zircon of Plešovice (337 Ma) (Sláma et al. Reference Sláma, Košler, Condon, Crowley, Gerdes, Hanchar, Horstwood, Morris, Nasdala, Norberg and Schaltegger2008). The measured compositions were corrected for common Pb using non-radiogenic 204Pb. Corrections were sufficiently small to be insensitive to the choice of common Pb composition and an average of present-day crustal composition was used for the common Pb assuming that the common Pb was largely surface contamination introduced during the sample preparation (Stacey and Kramers, Reference Stacey and Kramers1975). Uncertainties on individual analyses are reported at 1 σ level. Weighted mean ages for pooled U/Pb (and Pb/Pb) analyses are quoted with a 95% confidence interval. The data reduction is done using the online program IsoplotR (Vermeesch, Reference Vermeesch2018).

Analyses of zircon reference Qinghu were interspersed with unknowns, and eight analyses yielded a weighted mean 206Pb/238U age of 160.6 ± 2.1 Ma (MSWD = 0.9), consistent, within error, of the reported value of 159.5 ± 0.2 (Li et al. Reference Li, Tang, Gong, Yang, Hou, Hu, Li, Liu and Li2013).

3. Results

Zircon crystals from the tuff sample QXHY-6 are mostly subhedral to euhedral, which are 75–180 μm in length and 35–80 μm in width, respectively (Fig. 2(a)). Oscillatory zones are distinct in the CL images (Fig. 2(a)), and the ratios of Th/U are mostly higher than 0.4 (Table S1), suggesting the zircons are of magmatic origin.

Figure 2. SIMS zircon U–Pb age for the tuffs sample QXHY-6. (a) Images of representative dated zircons (transmission light and CL) show the SIMS analysis dots (white ovals) and the 207Pb/206Pb ages. (b) Wetherill U–Pb concordia diagram. (c) Weighted average of the 207Pb/206Pb ages.

Excluding two obvious outliers, 28 of 30 analyses yielded a relatively consistent 207Pb/206Pb age ranging from 1564 Ma to 1678 Ma, respectively. They lie on a discordia line going through zero in the U–Pb concordia plot with an upper intercept of 1588.8 ± 6.5 Ma (Fig. 2(b)), indicating that they suffered recent Pb loss. The upper intercept age of 1588.8 ± 6.5 Ma is consistent with the weighted mean age of 207Pb/206Pb within error (1589.1 ± 6.5 Ma, Fig. 2(c)), representing the crystallization age of these zircons.

4. Discussion and conclusion

These macrofossils are important for our understanding of early eukaryote evolution and associated biological innovation. In this study, we present a new SIMS U–Pb zircon age from a volcanic tuff above the macrofossil-bearing horizon in the same section. A discordia line going through zero in the U–Pb concordia plot indicates these zircons suffered recent Pb loss. The 207Pb/206Pb system was maintained during the stoichiometric loss of total lead, contributing to the consistent 207Pb/206Pb ages of these zircons (Spencer et al. Reference Spencer, Kirkland and Taylor2016). The upper intercept age of 1588.8 ± 6.5 Ma, which is consistent with the weighted mean 207Pb/206Pb age within error, is interpreted as the depositional age of this tuff, and a direct age constraint on the macrofossil horizon.

Zircons from tuff layers in the Gaoyuzhuang Formation in other sections were previously dated by laser ablation inductively coupled plasma mass spectrometry (LA-ICPMS) and sensitive high-resolution-ion microprobe (SHRIMP). Ages of 1582 ± 12 Ma (SHRIMP) and 1577 ± 12 Ma (LA-MC-ICPMS) were obtained from a volcanic tuff at the bottom of Member 3 of the Gaoyuzhuang Formation in the Jizhou section (Tian et al. Reference Tian, Zhang and Li2015, Reference Tian, Li and Zhang2020), and ages of 1560 ± 5 Ma (LA-MC-ICPMS) and 1559 ± 12 Ma (SHRIMP) were obtained from a tuff at the top of Member 3 in the Yanqing section (Li et al. Reference Li, Zhu, Xiang, Wenbo, Songnian, Hongying, Jianzhen, Sheng and Fengjie2010). These two sets of ages constrained Member 3 to ca. 1580–1560 Ma. Within the lithostratigraphic framework, the new dated horizon at the top of Member 3 at Qianxi section approximately corresponds to the ca. 1560 Ma volcanic ash layers in the Yanqing section.

At face value, the newly obtained date seems to be older than the previously published radio-isotopic date from the equivalent horizons in the Yanqing section. This apparent difference could be reconciled by the precision of 1–2% of these methods (Gehrels, Reference Gehrels2014; Yang et al. Reference Yang, Li, Zhu and Condon2017) or reflects the lithostratigraphic diachroneity. Within the wide distribution range of the Gaoyuzhuang Formation, the thickness of Member 3 varies greatly in the Yanshan Range (Fig. 1(b)). In Jizhou, Tianjin, the thickness is up to ca. 680 m (Shang et al. Reference Shang, Tang, Shi, Zhou, Zhou, Song and Jiang2019), while it is ca. 470 m in Qianxi (Chen et al. Reference Chen, Miao, Zhao and Zhu2023). Depending on the lithostratigraphic subdivision, the thickness of Member 3 was reported to be ca. 190 m (Shang et al. Reference Shang, Tang, Shi, Zhou, Zhou, Song and Jiang2019) or ca. 300 m (Mei, Reference Mei2007) in the Gan’gou section of Yanqing. The lithological characteristics of Member 3 also vary largely (Fig. 1(b)). Nodular limestones at the bottom are obvious at the Yanqing and Jizhou sections (Shang et al. Reference Shang, Tang, Shi, Zhou, Zhou, Song and Jiang2019), but are missing at the Qianxi section (Chen et al. Reference Chen, Miao, Zhao and Zhu2023). Limestone is also absent at the Qianxi section, but common in the Jizhou and Yanqing sections. With much wider distribution than the underlying Dahongyu Formation, the Gaoyuzhuang Formation is considered to have formed during a continued marine transgression (Huang, Reference Huang2006). The erosion–deposition processes can lead to the spatial and temporal variations of the depositional sequences (Meng et al. Reference Meng, Wei, Qu and Ma2011).

In most cases, lithostratigraphic boundaries are diachronous, and are not considered as precise markers for temporal correlation. The new SIMS U–Pb zircon age provides a direct age constraint on the macroscopic eukaryotic fossils, and; therefore, is critical for better understanding the evolution of multicellular organisms with environmental change (Yang et al. Reference Yang, Li, Selby, Wan, Guan, Zhou and Li2022).

At Jizhou section, evidence for a progressive oxygenation event was found in the lower part of Member 3, the approximate level of the macrofossil horizon at Qianxi section (Zhang et al. Reference Zhang, Zhu, Wood, Shi, Gao and Poulton2018). The evidence was verified by subsequent studies in other areas with different methods, which suggest an important link between the development of macroscopic life and oceanic oxygenation at this time (Shang et al. Reference Shang, Tang, Shi, Zhou, Zhou, Song and Jiang2019; Tang et al. Reference Tang, Fu, Shi, Zhou, Zheng, Li, Xu, Zhou, Xie, Zhu and Jiang2022; Xie et al. Reference Xie, Zhu, Wang, Xu, Zhou, Zhou, Shi and Tang2022; Ye et al. Reference Ye, Wang, Wang, Li, Wu and Zhang2023; Xu et al. Reference Xu, Qin, Wang, Li, Shi, Tang and Liu2023). However, neither chronological nor geochemical work on Member 3 were carried out in the Qianxi area, where most of those macrofossils with regularly repeated forms were found. The new age calls for biological and environmental studies to be carried out on the same stratigraphic section. Furthermore, a stratigraphic correlation framework is urgently needed to integrate biological and environmental studies that are carried out in different areas of the Yanshan Range, to obtain a holistic perspective on the relationship between the evolution of life and the environment.

The early Mesoproterozoic was thought to be characterized by generally low environmental oxygen concentrations, which restricted the emergence and evolution of multicellular organisms (Holland, Reference Holland2006; Lyons et al. Reference Lyons, Reinhard and Planavsky2014). The origin of eukaryotic multicellularity was thought to have a later occurrence after the oxygen levels increased. Molecular clocks estimate that multicellular eukaryotes originated at the transition between the Mesoproterozoic and Neoproterozoic (Sharpe et al. Reference Sharpe, Eme, Brown, Roger, Ruiz-Trillo and Nedelcu2015). However, more and more fossil evidence indicates that multicellular eukaryotes made their appearances in the early Mesoproterozoic and may have appeared even earlier (Javaux and Lepot, Reference Javaux and Lepot2018).

With the new direct age constraint reported herein, the macroscopic eukaryotic fossils from the Gaoyuzhuang Formation suggest that macroscopic life had already evolved in moderate diversity and certain morphological complexity at the beginning of the Mesoproterozoic. These new insights also emphasize the possibility of finding fossils of multicellular eukaryotes during this period and even earlier to the Paleoproterozoic.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S0016756824000220

Acknowledgements

This work was supported by the National Key Research and Development Program of China (2022YFF0800100), the National Natural Science Foundation of China (41921002) and Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences (E221110015). We thank Sheng He from the Beijing Research Institute of Uranium Geology for assistance in SIMS zircon U–Pb analysis.

Competing interests

The authors of the paper declare no conflict of interest.

References

Bonner, JT (1998) The origins of multicellularity. Integrative Biology: Issues, News, and Reviews 1, 2736.Google Scholar
Chen, K, Miao, L, Zhao, F and Zhu, M (2023) Carbonaceous macrofossils from the early Mesoproterozoic Gaoyuzhuang Formation in the Yanshan Range, North China. Precambrian Research 392, 107074.Google Scholar
Gehrels, G (2014) Detrital zircon U-Pb geochronology applied to tectonics. Annual Review of Earth and Planetary Sciences 42, 127149.Google Scholar
Holland, HD (2006) The oxygenation of the atmosphere and oceans. Philosophical Transactions of the Royal Society B: Biological Sciences 361, 903915.Google Scholar
Huang, X (2006) Tectonic evolution of the Meso-Neoproterozoic sedimentary basin in Yanshan range. Geological Survey and Research 29, 263270.Google Scholar
Javaux, EJ and Lepot, K (2018) The Paleoproterozoic fossil record: implications for the evolution of the biosphere during Earth’s middle-age. Earth-Science Reviews 176, 6886.Google Scholar
Li, H, Zhu, S, Xiang, Z, Wenbo, S, Songnian, L, Hongying, Z, Jianzhen, G, Sheng, L and Fengjie, Y (2010) Zircon U-Pb dating on tuff bed from Gaoyuzhuang Formation in Yanqing, Beijing: further constraints on the new subdivision of the Mesoproterozoic stratigraphy in the northern North China Craton. Acta Petrologica Sinica 26, 21312140.Google Scholar
Li, X, Liu, Y, Li, Q, Guo, C and Chamberlain, K (2009) Precise determination of Phanerozoic zircon Pb/Pb age by multicollector SIMS without external standardization. Geochemistry, Geophysics, Geosystems 10, Q04010.Google Scholar
Li, X, Tang, G, Gong, B, Yang, Y, Hou, K, Hu, Z, Li, Q, Liu, Y and Li, W (2013) Qinghu zircon: a working reference for microbeam analysis of U-Pb age and Hf and O isotopes. Chinese Science Bulletin 58, 46474654.Google Scholar
Liang, T and Jones, B (2021) Characteristics of primary rare earth elements and yttrium in carbonate rocks from the Mesoproterozoic Gaoyuzhuang Formation, North China: implications for the depositional system. Sedimentary Geology 415, 105864.Google Scholar
Lyons, TW, Reinhard, CT and Planavsky, NJ (2014) The rise of oxygen in Earth’s early ocean and atmosphere. Nature 506, 307315.Google Scholar
Mei, M (2007) Sedimentary features and their implication for the depositional succession of non-stromatolitic carbonates, Mesoproterozoic Gaoyuzhuang Formation in Yanshan area of North China. Geoscience 21, 4556.Google Scholar
Mei, M and Tucker, ME (2011) Molar tooth structure: a contribution from the Mesoproterozoic Gaoyuzhuang Formation, Tianjin City, North China. Acta Geologica Sinica - English Edition 85, 10841099.Google Scholar
Meng, Q, Wei, H, Qu, Y and Ma, S (2011) Stratigraphic and sedimentary records of the rift to drift evolution of the northern North China craton at the Paleo- to Mesoproterozoic transition. Gondwana Research 20, 205218.Google Scholar
Niklas, KJ and Newman, SA (2020) The many roads to and from multicellularity. Journal of Experimental Botany 71, 32473253.Google Scholar
Shang, M, Tang, D, Shi, X, Zhou, L, Zhou, X, Song, H and Jiang, G (2019) A pulse of oxygen increase in the early Mesoproterozoic ocean at ca. 1.57–1.56 Ga. Earth and Planetary Science Letters 527, 115797.Google Scholar
Sharpe, SC, Eme, L, Brown, MW and Roger, AJ (2015) Timing the origins of multicellular eukaryotes through phylogenomics and relaxed molecular clock analyses. In Evolutionary Transitions to Multicellular Life: Principles and mechanisms (eds Ruiz-Trillo, I, Nedelcu, AM), pp. 329. Dordrecht: Springer Netherlands.Google Scholar
Shi, M, Feng, Q, Khan, MZ and Zhu, S (2017) An eukaryote-bearing microbiota from the early mesoproterozoic Gaoyuzhuang Formation, Tianjin, China and its significance. Precambrian Research 303, 709726.Google Scholar
Sláma, J, Košler, J, Condon, DJ, Crowley, JL, Gerdes, A, Hanchar, JM, Horstwood, MS, Morris, GA, Nasdala, L, Norberg, N and Schaltegger, U (2008) Plešovice zircon—a new natural reference material for U-Pb and Hf isotopic microanalysis. Chemical Geology 249, 135.Google Scholar
Spencer, CJ, Kirkland, CL and Taylor, RJM (2016) Strategies towards statistically robust interpretations of in situ U–Pb zircon geochronology. Geoscience Frontiers 7, 581589.Google Scholar
Stacey, JS and Kramers, JD, (1975) Approximation of terrestrial lead isotope evolution by a two-stage model. Earth and Planetary Science Letters 26, 207221.Google Scholar
Tang, D, Fu, X, Shi, X, Zhou, L, Zheng, W, Li, C, Xu, D, Zhou, X, Xie, B, Zhu, X and Jiang, G (2022) Enhanced weathering triggered the transient oxygenation event at ∼1.57 Ga. Geophysical Research Letters 49, e2022GL099018.Google Scholar
Tian, H, Zhang, J, Li, H, et al. (2015) Zircon LA-MC-ICPMS U-Pb dating of tuff from Mesoproterozoic Gaoyuzhuang Formation in Jizhou county of North China and its geological significance. Acta Geosci Sin 36, 647658.Google Scholar
Tian, H, Li, H, Zhang, J, et al. (2020) SHRIMP U-Pb dating for zircons from the tuff bed of the Mesoproterozoic Gaoyuzhuang Formation in Jizhou Section, Tianjin, and its constraints on the Mesoproterozoic bio-environmental events. Geological Survey and Research 43, 153160.Google Scholar
Tian, S, Zhai, Z (1996) Petrostratigraphy of Tianjin. Wuhan: China University of Geosciences Press.Google Scholar
Vermeesch, P (2018) IsoplotR: a free and open toolbox for geochronology. Geoscience Frontiers 9, 14791493.Google Scholar
Xie, B, Zhu, J, Wang, X, Xu, D, Zhou, L, Zhou, X, Shi, X and Tang, D (2022) Mesoproterozoic oxygenation event: from shallow marine to atmosphere. GSA Bulletin 135, 753766.Google Scholar
Xu, D, Qin, Z, Wang, X, Li, J, Shi, X, Tang, D and Liu, J (2023) Extensive sea-floor oxygenation during the early Mesoproterozoic. Geochimica et Cosmochimica Acta 354, 186196.Google Scholar
Yang, C, Li, X, Zhu, M and Condon, DJ (2017) SIMS U–Pb zircon geochronological constraints on upper Ediacaran stratigraphic correlations, South China. Geological Magazine 154, 12021216.Google Scholar
Yang, C, Li, Y, Selby, D, Wan, B, Guan, C, Zhou, C and Li, XH (2022) Implications for Ediacaran biological evolution from the ca. 602 Ma Lantian biota in China. Geology 50, 562566.Google Scholar
Ye, Y, Wang, H, Wang, X, Li, J, Wu, C and Zhang, S (2023) Regional and global proxies for varying ocean redox conditions at ∼1.57 Ga: a causal connection with volcanism-induced weathering. Geosystems and Geoenvironment 2, 100173.Google Scholar
Zhang, K, Zhu, X, Wood, RA, Shi, Y, Gao, Z and Poulton, SW (2018) Oxygenation of the Mesoproterozoic ocean and the evolution of complex eukaryotes. Nature Geoscience 11, 345350.Google Scholar
Zhu, S, Zhu, M, Knoll, AH, Yin, Z, Zhao, F, Sun, S, Qu, Y, Shi, M and Liu, H (2016) Decimetre-scale multicellular eukaryotes from the 1.56-billion-year-old Gaoyuzhuang Formation in North China. Nature Communications 7, 11500.Google Scholar
Figure 0

Figure 1. Geological setting of the sample. (a) Distribution of Proterozoic outcrops in the Yanshan Range showing the reported tuff locations. (b) Correlation of the horizons of reported zircon U–Pb ages and fossils at (1) Yanqing, (2) Jizhou and (3) Qianxi. (c) Outcrop photograph of the tuff bed (yellow arrow) in the section. (d) Macrofossils (red arrows) from Member 3 of the Gaoyuzhuang Formation in Qianxi, Hebei.

Figure 1

Figure 2. SIMS zircon U–Pb age for the tuffs sample QXHY-6. (a) Images of representative dated zircons (transmission light and CL) show the SIMS analysis dots (white ovals) and the 207Pb/206Pb ages. (b) Wetherill U–Pb concordia diagram. (c) Weighted average of the 207Pb/206Pb ages.

Supplementary material: File

Chen et al. supplementary material

Chen et al. supplementary material
Download Chen et al. supplementary material(File)
File 30 KB