Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-20T17:30:01.891Z Has data issue: false hasContentIssue false

New materials of acanthomorphic acritarchs from the Ediacaran Weng'an Biota (South China)

Published online by Cambridge University Press:  31 May 2024

Junxian Wu
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing 210008, China College of Earth and Planetary Sciences, University of Chinese Academy of Sciences, Beijing 100049, China
Weichen Sun
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing 210008, China
Xiaodong Shang
Affiliation:
MNR Key Laboratory of Stratigraphy and Palaeontology, Institute of Geology, Chinese Academy of Geological Sciences, Beijing 100037, China
Pengju Liu
Affiliation:
MNR Key Laboratory of Stratigraphy and Palaeontology, Institute of Geology, Chinese Academy of Geological Sciences, Beijing 100037, China
Maoyan Zhu
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing 210008, China College of Earth and Planetary Sciences, University of Chinese Academy of Sciences, Beijing 100049, China Nanjing College, University of Chinese Academy of Sciences, Nanjing 211135, China
Zongjun Yin*
Affiliation:
State Key Laboratory of Palaeobiology and Stratigraphy, Nanjing Institute of Geology and Palaeontology, Chinese Academy of Sciences, Nanjing 210008, China Nanjing College, University of Chinese Academy of Sciences, Nanjing 211135, China
*
*Corresponding author.

Abstract

The Weng'an Biota from the Ediacaran Doushantuo Formation in Guizhou Province, southwestern China, is known for its three-dimensionally phosphatized acritarchs, multicellular algae, and embryo-like animal fossils. Among these diverse microfossils, acanthomorphic acritarchs have played a significant role in the biostratigraphic subdivision and correlation of the lower-middle Ediacaran System. However, most previous studies on the biostratigraphy of the Doushantuo Formation in the Weng'an area have focused on large acanthomorphic acritarchs (LAAs, vesicle diameter >200 μm), whereas the smaller acanthomorphic acritarchs (SAAs, vesicle diameter <100 μm) from the Weng'an Biota have been largely overlooked. In this study, we examined >500 thin sections and discovered a large number of well-preserved, small (<100 μm) and medium-sized acanthomorphic acritarchs (MAAs, vesicle diameter ranging 100–200 μm). In total, we have identified SAAs in four genera and six species (Tanarium conoideum Kolosova, 1991, emend. Moczydłowska et al., 1993; Tanarium elegans Liu et al., 2014; Mengeosphaera membranifera Shang, Liu, and Moczydłowska, 2019; Mengeosphaera minima Liu et al., 2014; Estrella recta Liu and Moczydłowska, 2019; Variomargosphaeridium gracile Xiao et al., 2014), as well as two types of MAAs (Tanarium tuberosum Moczydłowska, Vidal, and Rudavskaya, 1993, emend. Moczydłowska, 2015; Weissiella cf. W. grandistella Vorob'eva, Sergeev, and Knoll, 2009, emend. Liu and Moczydłowska, 2019). This updated acritarch assemblage of the Weng'an Biota is valuable for correlating the Ediacaran Doushantuo Formation between the Weng'an and Yangtze Gorges areas. It also serves as a tool to test the proposed acritarch biozones in Ediacaran formations of South China and other localities, including Australia, Siberia, and the East European Platform.

Type
Articles
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Paleontological Society

Non-technical Summary

The Weng'an Biota, found in the Doushantuo Formation in Guizhou Province, South China, is a remarkable fossil assemblage known for its well-preserved ancient life forms. These include small organisms called acritarchs, algae, and even embryo-like fossils. Among these, acritarchs, shaped like spiny spheres, have been essential for understanding the age and relationships of rocks from the Ediacaran Period. Previous studies mainly focused on larger spiny acritarchs, overlooking the smaller ones. In our study, we carefully examined over 500 thin sections and discovered a wealth of well-preserved small and medium-sized acritarchs. These tiny fossils, with diameters ranging 20–150 μm, help us understand the ancient ecosystems and how life evolved during this critical time in Earth's history. We identified several different species of small spiny acritarchs, e.g., Tanarium conoideum, Tanarium elegans, Mengeosphaera membranifera, Mengeosphaera minima, and Variomargosphaeridium gracile. Additionally, we found medium-sized acritarchs, e.g., Tanarium tuberosum and Weissiella cf. W. grandistella. These new findings provide important clues for correlating the rocks of the Doushantuo Formation in the Weng'an area with those in the Yangtze Gorges region. They also help us understand the evolution of acritarchs in different parts of the world, including Australia, Siberia, and the East European Platform.

Introduction

The Ediacaran Period witnessed the evolution of the Earth-Life system from Snowball Earth to the Cambrian explosion, making it one of the most critical transitional periods in the entire geological history (Narbonne et al., Reference Narbonne, Xiao, Shields, Gradstein, Ogg and Schmitz2012; Xiao and Narbonne, Reference Xiao, Narbonne, Gradstein, Ogg, Schmitz and Ogg2020). Many important events in the evolution of life and the environment, e.g., the origin and early radiation of metazoans and the Neoproterozoic Oxygenation Event (NOE), occurred during the Ediacaran Period and left numerous significant geological records worldwide (e.g., Xiao and Knoll, Reference Xiao and Knoll2000, Reference Xiao and Knoll2007). Consequently, a broadly accepted internal subdivision scheme and chronostratigraphic framework for the Ediacaran System is essential, because it forms the basis for studying the coevolution of biology and the environment during this period. However to date, the internal subdivision scheme and a standard for regional stratigraphic correlation for the Ediacaran System are still under debate (Steiner et al., Reference Steiner, Li, Qian, Zhu and Erdtmann2007; Liu et al., Reference Liu, Chen, Zhu, Li, Yin and Shang2014b; Zhou et al., Reference Zhou, Yuan, Xiao, Chen and Hua2019; Zhu et al., Reference Zhu, Yang, Yuan, Li, Zhang, Zhao, Ahn and Miao2019).

Ediacaran large acanthomorphic acritarchs (LAAs, with diameter normally > 200 μm) are globally distributed microfossils and exhibit high diversity, playing a crucial role in biostratigraphic subdivisions and correlation of the Ediacaran System (Vidal, Reference Vidal1990; Vorob'eva et al., Reference Vorob'eva, Sergeev and Knoll2009; Golubkova et al., Reference Golubkova, Raevskaya and Kuznetsov2010; Sergeev et al., Reference Sergeev, Knoll and Vorob'eva2011; Anderson et al., Reference Anderson, Macdonald, Jones, McMahon and Briggs2017). In 2005, Grey established five acritarch assemblage zones based on LAA fossils for the Ediacaran System of Australia (Grey, Reference Grey2005), and this scheme has gained support from other studies (Willman et al., Reference Willman, Moczydłowska and Grey2006; Willman and Moczydłowska, Reference Willman and Moczydłowska2008, Reference Willman and Moczydłowska2011; Sergeev et al., Reference Sergeev, Knoll and Vorob'eva2011), indicating that LAAs could be a valuable tool for the internal subdivision and global correlation of the Ediacaran System.

Since the 1970s, abundant LAAs have been discovered in the Ediacaran Doushantuo Formation in South China (Yin and Li, Reference Yin and Li1978; McFadden et al., Reference McFadden, Xiao, Zhou and Kowalewski2009; Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a; Liu and Moczydłowska, Reference Liu and Moczydłowska2019). Based on extensive investigation of taxonomic diversity, Liu and Moczydłowska (Reference Liu and Moczydłowska2019) established four acritarch assemblage zones for the Ediacaran Doushantuo Formation in the Yangtze Gorges area. However, biostratigraphic correlation between the Ediacaran Doushantuo Formation of Yangtze Gorges area, South China, and the Ediacaran Pertatataka and Julie formations of Australia has long been difficult due to two reasons. First, silicified acanthomorphic acritarchs from chert nodules (Xiao et al., Reference Xiao, Schiffbauer, McFadden and Hunter2010) revealed by thin sections look different from carbonaceous acritarchs extracted from shales using acid maceration, even for the same species. Second, many acritarchs are mainly local species with limited significance in global biostratigraphic correlations. Therefore, how to correlate Ediacaran acritarch assemblage zones of South China with that of Australia, Siberia, and the Eastern European Platform remains uncertain. To resolve the problem, more investigations on acritarch diversity and taxonomy are needed. In addition, although previous studies have established four acritarch assemblage zones for the Ediacaran Doushantuo Formation in the Yangtze Gorges area (Liu and Moczydłowska, Reference Liu and Moczydłowska2019), it remains uncertain whether the scheme of these four biozones is applicable to the Ediacaran Doushantuo Formation in the Weng'an area.

In this study, we focused on the fossil assemblage of acanthomorphic acritarchs from the Ediacaran Doushantuo Formation in the Weng'an area of Guizhou Province, southwestern China. Unlike many small acanthomorphic acritarchs (SAAs, with diameters < 100 μm) found in other regions, e.g., the Yangtze Gorges area in South China, Australia, Siberia, and the East European Platform, the majority of acanthomorphic acritarchs reported previously from the Weng'an Biota have diameters > 200 μm. For instance, Tianzhushania Yin and Li, Reference Yin and Li1978, emend. Yin, Zhou, and Yuan, Reference Yin, Zhou and Yuan2008 and Yinitianzhushania Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a have diameters that can exceed 600 μm. To date, a total of 25 genera and 47 species plus two undetermined species of acanthomorphic acritarchs (Table 1) have been described from the Weng'an Biota. Among them, 22 genera and 28 species belong to the LAAs. It is noteworthy that only eight genera and 10 species plus one undetermined genus of SAAs have been discovered in the Weng'an Biota (L. Yin et al., Reference Yin, Wang, Yuan and Zhou2011). Additionally, seven genera and eight species of medium-sized acritarchs (MAAs, with diameters ranging 100–200 μm) have been identified (Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a). The Weng'an SAAs include Appendisphaera grandis Moczydłowska, Vidal, and Rudavskaya, Reference Moczydłowska, Vidal and Rudavskaya1993, emend. Moczydłowska, Reference Moczydłowska2005; Bullatosphaera sp. indet.; Dicrospinasphaera virgata Grey, Reference Grey2005; Dicrospinasphaera zhangii Yuan and Hofmann, Reference Yuan and Hofmann1998; Eotylotopalla delicata Yin, Reference Yin1987; Hocosphaeridium anozos (Willman in Willman and Moczydłowska, Reference Willman and Moczydłowska2008) Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; Mengeosphaera chadianensis (Chen and Liu, Reference Chen and Liu1986) Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; Tanarium digitiforme (Nagovitsin and Faizullin in Nagovitsin et al., Reference Nagovitsyn, Faizullin and Yakshin2004) Sergeev, Knoll, and Vorob'eva, Reference Sergeev, Knoll and Vorob'eva2011; Tanarium victor Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; Taedigerasphaera lappacea Grey, Reference Grey2005; and Variomargosphaeridium gracile Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a. The MAAs include Asterocapsoides sinensis Yin and Li, Reference Yin and Li1978, emend. Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; Asterocapsoides wenganensis (Chen and Liu, Reference Chen and Liu1986) Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; Cavaspina acuminata (Kolosova, Reference Kolosova1991) Moczydłowska, Vidal, and Rudavskaya, Reference Moczydłowska, Vidal and Rudavskaya1993; Eotylotopalla dactylos Zhang et al., Reference Zhang, Yin, Xiao and Knoll1998; Ericiasphaera rigida Zhang et al., Reference Zhang, Yin, Xiao and Knoll1998; Mengeosphaera reticulata (Xiao and Knoll, Reference Xiao and Knoll1999) Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; Papillomembrana boletiformis Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; and Taeniosphaera doushantuoensis Liu and Yin, Reference Liu and Yin2005 (Table 1). Considering that the diversity of small and medium-sized acritarchs in the Weng'an Biota has not been fully explored, this study focuses on them to uncover additional clues for Ediacaran biostratigraphic correlation.

Table 1. Small and medium-sized acanthomorphs from the Doushantuo Formation in the Weng'an area, records from the published literature and this study. EEP = East European Platform; 1 = Chen, Reference Chen2004; 2 = Chen and Liu, Reference Chen and Liu1986; 3 = Chen et al., Reference Chen, Yin, Liu, Gao, Tang and Wang2010; 4 = Golubkova et al., Reference Golubkova, Raevskaya and Kuznetsov2010; 5 = Grey, Reference Grey2005; 6 = Knoll, Reference Knoll1992; 7 = Kolosova, Reference Kolosova1991; 8 = Liu et al., Reference Liu, Yin, Chen, Tang and Gao2012; 9 = Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a; 10 = Liu and Moczydłowska, Reference Liu and Moczydłowska2019; 11 = Moczydłowska, Reference Moczydłowska2005; 12 = Moczydłowska and Nagovitsin, Reference Moczydłowska and Nagovitsin2012; 13 = Moczydłowska et al., Reference Moczydłowska, Vidal and Rudavskaya1993; 14 = Nagovitsin et al., Reference Nagovitsyn, Faizullin and Yakshin2004; 15 = Sergeev et al., Reference Sergeev, Knoll and Vorob'eva2011; 16 = Veis et al., Reference Veis, Vorob'eva and Goubkova2006; 17 = Vorob'eva et al., Reference Vorob'eva, Sergeev and Knoll2009; 18 = Vorob'eva et al., Reference Vorob'eva, Sergeev and Chumakov2008; 19 = Willman and Moczydłowska, Reference Willman and Moczydłowska2008; 20 = Willman and Moczydłowska, Reference Willman and Moczydłowska2011; 21 = Xiao, Reference Xiao2004; 22 = Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; 23 = Xiao and Knoll, Reference Xiao and Knoll1999; 24 = Xiao et al., Reference Xiao, Knoll, Zhang and Hua1999; 25 = Xie et al., Reference Xie, Zhou, Mcfadden, Xiao and Yuan2008; 26 = Yin, Reference Yin1987; 27 = Yin, Reference Yin1990; 28 = Yin and Li, Reference Yin and Li1978; 29 = C. Yin et al., Reference Yin, Liu, Awramik, Chen, Tang, Gao, Wang and Riedman2011; 30 = Yin et al., Reference Yin, Zhu, Knoll, Yuan, Zhang and Hu2007; 31 = L. Yin et al., Reference Yin, Wang, Yuan and Zhou2011; 32 = Yin et al., Reference Yin, Zhu, Tafforeau, Chen, Liu and Li2013; 33 = Yuan and Hofmann, Reference Yuan and Hofmann1998; 34 = Yuan et al., Reference Yuan, Xiao, Yin, Knoll, Zhou and Mu2002; 35 = Zang and Walter, Reference Zang and Walter1992; 36 = Zhang et al., Reference Zhang, Yin, Xiao and Knoll1998; 37 = Zhou et al., Reference Zhou, Brasier and Xue2001; 38 = Zhou et al., Reference Zhou, Chen and Xue2002a; 39 = Zhou et al., Reference Zhou, Xie, Mcfadden, Xiao and Yuan2007; 40 = Zhou et al., Reference Zhou, Yuan and Xiao2002b; 41 = Zhou et al., Reference Zhou, Yuan, Xiao, Chen and Xue2004; 42 = Shang et al., Reference Shang, Liu and Moczydłowska2019; 43 = Ouyang et al., Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021; * = diameter < 100 μm; ** = medium-sized acritarchs reported by this study; # = species reported previously with diameter <100μm.

Geological setting

Geological investigation of the Doushantuo Formation in the Weng'an area started in the 1960s (Xiao et al., Reference Xiao, Muscente, Chen, Zhou, Schiffbauer, Wood, Polys and Yuan2014b). The Doushantuo Formation in the Weng'an phosphorite mining area, located in Guizhou Province, southwestern China (Fig. 1.1), outcrops in a pattern controlled by a north/northeast to south/southwest-trending Baiyan-Gaoping anticline (Fig. 1.2). A generalized stratigraphic column of the Doushantuo Formation in this area is displayed in Figure 1.3 (Xiao et al., Reference Xiao, Muscente, Chen, Zhou, Schiffbauer, Wood, Polys and Yuan2014b; Cunningham et al., Reference Cunningham, Vargas, Yin, Bengtson and Donoghue2017). The entire formation is composed of five units, arranged from bottom to top as follows: cap dolomite (Unit 1), the lower phosphorite (Unit 2), the middle dolomite (Unit 3), the upper phosphorite (Unit 4), and the phosphoritic dolomite members (Unit 5). Detailed description of lithostratigraphy for the Doushantuo Formation in the Weng'an area can be found in numerous previous publications (Xiao et al., Reference Xiao, Zhang and Knoll1998, Reference Xiao, Zhou, Liu, Wang and Yuan2014a; Yin et al., Reference Yin, Zhu, Davidson, Bottjer, Zhao and Tafforeau2015; Zhou et al., Reference Zhou, Li, Xiao, Lan, Ouyang, Guan and Chen2017).

Figure 1. The geological setting of Weng'an area. (1) Relationships between the Yangtze Block (YB), North China Block (NCB), and Tarim Block (TB). A red star marks the locality of the Weng'an phoshorite mining area. (2) Geological setting of the Weng'an area; the outcrop is marked by a red star. (3) Ediacaran stratigraphic column of the Beidoushan section in the Weng'an area showing the fossil horizon. Modified from Yin et al., Reference Yin, Zhu, Davidson, Bottjer, Zhao and Tafforeau2015.

The Weng'an Biota was described from the upper phosphorite (Unit 4), which consists of the lower black phosphorite facies (Unit 4A) and upper gray phosphatic dolomite facies (Unit 4B). Although the depositional age range for the Doushantuo Formation is well dated, ranging 635–551 Ma (Condon et al., Reference Condon, Zhu, Bowring, Wang, Yang and Jin2005), the Weng'an Biota has long lacked precise isotopic age constraints. There are two karstic surfaces that have developed in the Doushantuo Formation in the Weng'an area, one at the top of Unit 3 and the other within Unit 5 (Zhu et al., Reference Zhu, Zhang and Yang2007, Reference Zhu, Lu, Zhang, Zhao, Li, Aihua, Zhao and Zhao2013, Reference Zhu, Yang, Yuan, Li, Zhang, Zhao, Ahn and Miao2019). If the lower karstic surface can be correlated to the 582 Ma Gaskiers glaciation (Condon et al., Reference Condon, Zhu, Bowring, Wang, Yang and Jin2005), then the Weng'an Biota would be younger than 582 Ma. However, if the upper karstic surface correlates to the Gaskiers glaciation (Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a), then the Weng'an Biota would be much older than 582 Ma. A U-Pb age of 609 ± 5 Ma, determined from the ash bed immediately above Unit 4 of the Ediacaran Doushantuo Formation at the Zhancunping section in Hubei Province, correlates with Unit 4A of the Ediacaran Doushantuo Formation at the Weng'an area. This age constraint provides important chronological information for the Weng'an Biota (Zhou et al., Reference Zhou, Yuan, Xiao, Chen and Hua2019). However, based on new CA-ID-TIMS U-Pb analyses, Yang et al. (Reference Yang, Rooney, Condon, Li, Grazhdankin, Bowyer, Hu, Macdonald and Zhu2021) claimed that zircons from the same ash bed have a detrital origin with maximum depositional age of 612.5 ± 0.9 Ma. Through chemo- and biostratigraphic correlation, Yang et al. (Reference Yang, Rooney, Condon, Li, Grazhdankin, Bowyer, Hu, Macdonald and Zhu2021) proposed that the age of the Weng'an Biota likely ranges 575–590 Ma.

Materials and methods

The specimens reported in this study were collected from the black phosphorite facies (Unit 4A) of the Doushantuo Formation in the Weng'an area (Fig. 1.3). More than 500 thin sections were examined to search for microfossils under a transmitted light microscope (Nikon Ni-U microscope). All acanthomorphic acritarchs revealed in thin sections were recorded with stage coordinates, and then photographed with a Nikon FIT-1 CCD camera. Measurements for vesicle diameter, length, quantity, and basal width of processes were conducted on high-resolution photographs using Image J (http://imagej.nih.gov/ij); the measured data are provided in Appendix 1.

Repository and institutional abbreviation

Microfossils illustrated here are reposited at the Nanjing Institute of Geology and Palaeontology, Chinese Academy of Science, Nanjing, China (NIGPAS).

Systematic paleontology

In this study, we adhered to the criteria established by Xiao et al. (Reference Xiao, Zhou, Liu, Wang and Yuan2014a) to define vesicle size, which is quantitatively diagnosed as small (<100 μm diameter), medium-sized (100–200 μm diameter), or large (>200 μm diameter). In acritarch taxonomy, the characteristics of processes (e.g., morphology, density, branching, and whether hollow processes communicate with the vesicle interior; Fig. 2) play a significant role. A systematic description is given in alphabetic order for acanthomorphic acritarch taxa below.

Figure 2. Schematic drawings of acritarchs: (1) Estrella recta Liu and Moczydłowska, Reference Liu and Moczydłowska2019; (2) Mengeosphaera membranifera Shang, Liu, and Moczydłowska, Reference Liu and Moczydłowska2019; (3) M. minima Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a; (4) Tanarium conoideum Kolosova, Reference Kolosova1991; (5) Tanarium elegans Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a; (6) Tanarium tuberosum Moczydłowska, Vidal, and Rudavskaya, Reference Moczydłowska, Vidal and Rudavskaya1993, emend. Moczydłowska, Reference Moczydłowska2015; (7) Variomargosphaeridium gracile Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; (8) Weissiella cf. W. grandistella Vorob'eva, Sergeev, and Knoll, Reference Vorob'eva, Sergeev and Knoll2009, emend. Liu and Moczydłowska, Reference Liu and Moczydłowska2019. The left scale bar is for (6) and (8); the right scale bar is for the others.

Group Acritarcha Evitt, Reference Evitt1963
Genus Estrella Liu and Moczydłowska, Reference Liu and Moczydłowska2019

Type species

Estrella greyae Liu and Moczydłowska, Reference Liu and Moczydłowska2019 from the Yangtze Gorges area, northern Xiaofenghe section, South China.

Estrella recta Liu and Moczydłowska, Reference Liu and Moczydłowska2019
Figures 2.1, 3

Reference Liu and Moczydłowska2019

Estrella recta Liu and Moczydłowska, p. 109, fig. 57A–F.

Figure 3. Estrella recta Liu and Moczydłowska, Reference Liu and Moczydłowska2019. Thin section numbers: (1) WS17-225-X42Y105, (2) WS17-225-X46Y106, (3) WS17-195-X54Y99, (4) WS17-157-X64Y101, (5) WS17-259-X19.5Y113, (6) WS17-211-X35Y94.

Holotype

Thin section nos. IGCAGS-D2XFH200 and XFH0946-1-9, F48/4 from the Yangtze Gorges area, Nantuocun section, Member II of the Doushantuo Formation, South China (Liu and Moczydłowska, Reference Liu and Moczydłowska2019, p.108, fig. 57A–D).

Description

Small-sized spherical vesicle with an irregular outline resulting from collapse during taphonomic and diagenetic processes, bearing homomorphic and regularly distributed hollow processes. The processes are elongated tubular structures that taper toward their distal portions, ending in sharp tips. They are hollow and freely communicate with the vesicle cavity. The widened bases of processes create a wavy outline of the vesicle wall. Vesicle diameter 35–48 μm (mean 43 μm, N = 3); process length 8–27 μm (mean 19 μm, N = 47); process basal width 2–11 μm (mean 5 μm, N = 14); distance between processes 6–12 μm (mean 9 μm, N = 13); ~16–25 processes on the vesicle periphery in circumferential view.

Material

Five well-preserved specimens and one poorly preserved specimen from Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area.

Remarks

The species is distinguished by its robust hollow processes, characterized by an elongate conical shape and bulbous bases. Vesicles exhibit a circular shape with a slightly undulating outline (Fig. 3). Due to taphonomy and diagenesis, many specimens have undergone deformation. Consequently in some specimens, the length of processes exceeds the vesicle diameter, whereas in others, the length of processes is only half of the vesicle diameter. Although sharing similarities in vesicle size and process length with several species of the genus Tanarium Kolosova, Reference Kolosova1991—e.g., Tanarium gracilentum (Yin in Yin and Liu, Reference Yin, Liu, Zhao, Xing, Ding, Liu and Zhao1988) Ouyang et al., Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021, Tanarium pycnacanthum Grey, Reference Grey2005, and Tanarium paucispinosum Grey, Reference Grey2005—the species differs in process morphology and density. Both Tanarium gracilentum and Tanarium pycnacanthum feature more densely distributed processes (>100 processes in circumferential view). In contrast, Tanarium paucispinosum (with <10 processes in circumferential view) possesses more slender and more flexible processes compared to our specimens. Consequently, our specimens are classified as Estrella recta.

Genus Mengeosphaera Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a

Type species

Mengeosphaera chadianensis (Chen and Liu, Reference Chen and Liu1986) Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a from the Doushantuo Formation at Weng'an area, South China.

Mengeosphaera membranifera Shang, Liu, and Moczydłowska, Reference Liu and Moczydłowska2019
Figures 2.2, 4

Reference Shang, Liu and Moczydłowska2019

Mengeosphaera membranifera Shang et al., p. 18, fig. 15A–D.

Figure 4. Mengeosphaera membranifera Shang, Liu, and Moczydłowska, Reference Liu and Moczydłowska2019. Thin section numbers: (1) WS17-152-X62Y103, (2) WS17-231-X64Y108, (3) WS17-231-X27Y101, (4) WS17-204-X37Y93, (5) WS17-207-X30Y104, with green arrow indicating site of (6), (6) magnified view of (5).

Holotype

Thin section no. LJ101115-1-7 from the Songlin area of Guizhou Province, Liujing section of chert nodules in medium- to thick-bedded dolostones of the Ediacaran Doushantuo Formation, South China (Shang et al., Reference Shang, Liu and Moczydłowska2019, p. 18, fig. 15A–D).

Description

Small spheroidal vesicles exhibiting abundant, closely, and regularly arranged biform processes of uniform length, each surrounded by an outer membrane. The outer membrane is supported by processes, and the distance from the outer membrane to the bases of the processes remains constant within a single specimen. Processes consist of regular conical bases and cylindrical, thin apical spines with sharp tips. They are hollow and freely communicate with the vesicle interior. Vesicle diameter 40–48 μm (mean 43 μm, N = 4); process length 4–7 μm (mean 6 μm, N = 185); process basal width 1–2 μm (mean 2 μm, N = 17); distance between processes 1–4 μm (mean 3 μm, N = 19); ~40 processes in circumferential view.

Material

Five specimens from Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area.

Remarks

Acritarchs featuring an outer membrane supported by biform processes are rare in the Ediacaran Period, with known occurrences limited to chert nodules in the Liujing section, Songlin area of Guizhou Province, southwestern China (Shang et al., Reference Shang, Liu and Moczydłowska2019). Our specimens exhibit similarities to some Mengeosphaera gracilis Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a in terms of process morphology and share resemblance with species of Cymatiosphaeroides (Knoll, Reference Knoll1984) Knoll, Swett, and Mark, Reference Knoll, Swett and Mark1991 in the outer membrane structure. However, they differ from Mengeosphaera gracilis due to the presence of the outer membrane and are distinguished from Cymatiosphaeroides by their distinct biform processes. Therefore, despite its smaller size compared to the specimens described by Shang et al. (Reference Shang, Liu and Moczydłowska2019), our specimens align more closely with the diagnostic features of Mengeosphaera membranifera.

Mengeosphaera minima Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a
Figures 2.3, 5, 6

Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a

Mengeosphaera minima Liu et al., p. 69, 101, figs. 51.8, 63.

Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021

Mengeosphaera minima; Ouyang et al., p. 24, fig. 17M, N.

Reference Ye, Li, Tong, An, Hu and Xiao2022

Mengeosphaera minima; Ye et al., p. 52, fig. 32G, H.

Figure 5. Mengeosphaera minima Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a. Thin section numbers: (1) WS17-217-X48Y101, (2) WS17-153-X31Y91, (3) WS17-227-x57y97, (4) WS17-227-X46Y99, (5) WS17-231-X58Y112, (6) WS17-145-X50Y98.

Figure 6. Mengeosphaera minima Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a. Thin section numbers: (1) WS17-224-X45Y110, (2) WS17-235-X59Y107, (3) WS17-207-x17y99, (4) WS17-256-X36Y114, (5) WS17-220-X38Y100, (6) WS17-219-X25Y101. (1, 2) showing the multicellular structures within their vesicle (blue arrows).

Holotype

Thin section no. I IGCAGS-NPIII-090A from the Yangtze Gorges area, Niuping section of the upper Member III, Doushantuo Formation, South China (Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a, p. 69, fig. 63.1).

Description

Small spheroidal vesicle bearing abundant, closely, and evenly distributed biform processes. Each process consists of a conical base and a thin apical filament. Occasionally, the apical spine is curved at the distal end (Figs. 5.1, 5.3, 6.1, 6.4, white arrows). The processes are hollow and freely communicate with the vesicle interior. Some specimens show multicellular structure (Fig. 6.1, 6.2, blue arrows). Vesicle diameter 33–46 μm (mean 39 μm, N = 40); process length 5–13 μm (mean 8 μm, N = 1,432); process basal width 2–4 μm (mean 3 μm, N = 246); process spacing 3–6 μm (mean 4 μm, N = 233); ~21–60 processes on vesicle periphery in circumferential view.

Material

Forty-two specimens from Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area.

Remarks

The specimens illustrated in Figures 5 and 6 align with the diagnostic criteria of Mengeosphaera minima (Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a; Ouyang et al., Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021; Ye et al., Reference Ye, Li, Tong, An, Hu and Xiao2022). The presence of the curved spine might be a taphonomic artifact, because this feature was not consistently observed. Although approximately a dozen species of Mengeosphaera exhibit conical expansion of the process bases (please refer the fig. 51 and table 2 in Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a), only M. bellula Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a, M. minima, M. spicata Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a, and M. stegosauriformis Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a share small vesicle sizes comparable to our specimens. Notably, the basal parts of the processes in M. spicata and M. stegosauriformis are larger (basal width 7–20 μm for M. spicata and 20–22 μm for M. stegosauriformis, according to Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a). Additionally, M. bellula displays a different conical shape than M. minima.

Genus Tanarium Kolosova, Reference Kolosova1991, emend. Moczydłowska et al., Reference Moczydłowska, Vidal and Rudavskaya1993

Type species

Tanarium conoideum Kolosova, Reference Kolosova1991, emend. Moczydłowska, et al., Reference Moczydłowska, Vidal and Rudavskaya1993, from the Ediacaran (Vendian) Kursov Formation in the Yakutia area of the Siberian Platform (Kolosova, Reference Kolosova1991; Moczydłowska et al., Reference Moczydłowska, Vidal and Rudavskaya1993; Moczydłowska, Reference Moczydłowska2005).

Tanarium conoideum Kolosova, Reference Kolosova1991, emend. Moczydłowska et al., Reference Moczydłowska, Vidal and Rudavskaya1993
Figures 2.4, 7

Reference Kolosova1991

Tanarium conoideum Kolosova, p. 56, 57, fig. 5.1–5.3.

Reference Moczydłowska, Vidal and Rudavskaya1993

Tanarium conoideum; Moczydłowska et al., p. 514–516, fig. 10C, D.

Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a

Tanarium conoideum; Liu et al., p. 109, figs. 76.2, 77.1–77.6.

non Reference Prasad and Ramson2016

Tanarium conoideum; Prasad and Ramson, Reference Prasad and Ramson2016, p. 56, pl. 7, fig. 8.

Reference Shang, Liu and Moczydłowska2019

Tanarium conoideum; Shang et al., p. 26, fig. 16A–E.

non Reference Yang, Pang, Chen, Zhong and Yang2020

Tanarium conoideum; Yang et al., p. 6, 7, fig. 2K.

Reference Vorob'eva and Petrov2020

Tanarium conoideum; Vorob'eva and Petrov, p. 374, 375, pl. 1, fig. 15.

Reference Yang, Pang, Chen, Zhong and Yang2020

Tanarium conoideum; Yang et al., p. 8, fig. 2K.

Reference Ye, Li, Tong, An, Hu and Xiao2022

Tanarium conoideum; Ye et al., p. 61, fig. 42.

Holotype

Thin section no. YIGS Nr 87-115 from the Kursov Formation, Upper Proterozoic, Vendian of Yakulia, Siberian Piatform and Borehole Byk-Tanar area (Kolosova, Reference Kolosova1991, p. 56, fig. 5.1, 5.2).

Description

Small spherical vesicles, bearing a small number of conical processes. The bases of the processes are slightly expanded and distally tapered to a pointed tip, or sometimes blunt due to breakage. The processes are hollow, allowing for free communication with the vesicle interior. Vesicle diameter 33–45 μm (mean 40 μm, N = 6); process length 8–10 μm (mean 7 μm, N = 89); process basal width 3–4 μm (mean 4 μm, N = 27); distance between processes 5–8 μm (mean 7 μm, N = 35); ~7–27 processes on the vesicle periphery in circumferential view.

Material

Six specimens from Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area.

Remarks

Most processes are straight, with a few showing distal hooks (Fig. 7.2, 7.3, white arrows). According to Xiao et al. (Reference Xiao, Zhou, Liu, Wang and Yuan2014a), distally hooked processes can result from taphonomic alteration. Although the specimens in our collection are smaller than those previously reported for Tanarium conoideum, the process features align more closely with the diagnosis of Tanarium conoideum than with other species. The specimens diagnosed as Tanarium conoideum by Moczydłowska and Nagovitsin (Reference Moczydłowska and Nagovitsin2012) and Prasad and Ramson (Reference Prasad and Ramson2016), exhibit thin, short processes that are inconsistent with the diagnosis of Tanarium conoideum. Similarly, the specimen described as Tanarium conoideum by Yang et al. (Reference Yang, Pang, Chen, Zhong and Yang2020) has abundant, relatively short, densely distributed processes with basal expansions, leading to its exclusion from Tanarium conoideum.

Figure 7. Tanarium conoideum Kolosova, Reference Kolosova1991, emend. Moczydłowska et al., Reference Moczydłowska, Vidal and Rudavskaya1993. Thin section numbers: (1) WS17-210-X38Y103, (2) WS17-150-X47Y101, (3) WS17-234-X46Y99, (4) WS17-206-X25Y104, (5) WS17-208-X48Y98, (6) WS17-150-X50Y111.

Tanarium elegans Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a
Figures 2.5, 8.1, 8.2

Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a

Tanarium elegans Liu et al., p. 81, fig. 75.8–75.16.

Figure 8. (1, 2) Tanarium elegans Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a and (3, 4) Tanarium tuberosum Moczydłowska, Vidal, and Rudavskaya, Reference Moczydłowska, Vidal and Rudavskaya1993, emend. Moczydłowska, Reference Moczydłowska2015. Thin section numbers: (1) WS17-196-X40Y107, (2) WS17-150-X59.5Y108, (3) WS17-201-x42.5y93.5, (4) WS17-202-X57Y93.

Holotype

Thin section no. IGCAGS–XFH–270 from the Yangtze Gorges area, Xiaofenghe section of the lower Member II, Doushantuo Formation, South China (Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a, fig. 75.10).

Description

Small spheroidal vesicles exhibiting numerous evenly and regularly arranged conical processes. These processes, hollow in nature, freely communicate with the vesicle interior, and taper gradually to a blunt termination. Vesicle diameter 39 and 44 μm (only two specimens discovered during this study); process length 6–9 μm (mean 7 μm, N = 36); process basal width 1–3 μm (mean 2 μm, N = 4); > 30 processes in circumferential view.

Material

Two specimens from Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area.

Remarks

The specimens illustrated in Figures 8.1 and 8.2 align with the diagnostic criteria of Tanarium elegans. Tanarium elegans exhibits closest similarities to Tanarium acus Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a and Xenosphaera liantuoensis Yin, Reference Yin1987, emend. Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a in terms of small vesicle size and very thin processes. However, when compared to Tanarium elegans, Tanarium acus features relatively fewer but longer processes whereas Xenosphaera liantuoensis has a larger vesicle and longer processes. In addition, it is noteworthy that Tanarium elegans typically lacks a thin filamentous tip.

Tanarium tuberosum Moczydłowska, Vidal, and Rudavskaya, Reference Moczydłowska, Vidal and Rudavskaya1993,
emend. Moczydłowska, Reference Moczydłowska2015
Figures 2.6, 8.3, 8.4

Reference Moczydłowska, Vidal and Rudavskaya1993

Tanarium tuberosum Moczydłowska et al., p. 516, fig. 15B–D.

Reference Moczydłowska2015

Tanarium tuberosum; Moczydłowska, pl. 3, figs. 1–6.

Reference Prasad and Ramson2016

Tanarium tuberosum; Prasad and Ramson, p. 56, 58, pl. 8, figs. 1, 2.

Reference Liu and Moczydłowska2019

Tanarium tuberosum; Liu and Moczydłowska, p. 153–156, fig. 86, pl. 21, fig. 18A.

Reference Shang, Liu and Moczydłowska2019

Tanarium tuberosum; Shang et al., p. 27–29, fig. 18.

Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021

Tanarium tuberosum; Ouyang et al., p. 27, fig. 19R

Holotype

Thin section no. PMU-Sib.4-J/30/3 from the Nepa-Botuoba area, lowermost Kbamaka Formation, Neoproterozoic, Upper Vendian (Moczydłowska et al., Reference Moczydłowska, Vidal and Rudavskaya1993, p. 516, fig. 15B–D).

Description

Medium-sized spheroidal vesicle showcasing irregularly distributed wide conical processes. These processes, hollow and broad, feature blunt tips and freely communicate with the vesicle interior. Vesicle diameter 91 and 111 μm (only two specimens discovered during this study); process length 12–25 μm (mean 16 μm, N = 38); process basal width 6–11 μm (mean 9 μm, N = 14); distance between processes 6–23 μm (mean 14 μm, N = 11); ~12–26 processes on vesicle periphery in circumferential view.

Material

Two specimens from Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area.

Remarks

The current specimens exhibit irregularly conical processes and a medium-sized vesicle diameter (91–111 μm). The vesicle size is comparable to the specimens featured by Liu and Moczydłowska (Reference Liu and Moczydłowska2019). There is a slight difference in the process number of the specimens in Figures 8.3 and 8.4 that could be interpreted as infraspecific variability (Liu and Moczydłowska, Reference Liu and Moczydłowska2019).

Genus Variomargosphaeridium Zang and Walter, Reference Zang and Walter1992, emend. Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a

Type species

Variomargosphaeridium litoschum Zang and Walter, Reference Zang and Walter1992, Doushantuo Formation at Weng'an area, South China; Amadeus Basin, Rodinga 4 borehole at a depth of 48.38–48.67 m, Pertatataka Formation, Ediacaran successions in Australia.

Variomargosphaeridium gracile Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a
Figures 2.7, 9

Reference Xiao, Zhou, Liu, Wang and Yuan2014a

Variomargosphaeridium gracile Xiao et al., p. 58, fig. 36.

Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021

Variomargosphaeridium gracile; Ouyang et al., p. 31, fig. 22A.

Figure 9. Variomargosphaeridium gracile Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a. Thin section numbers: (1) WS17-150-X50Y110, (2) WS17-161-X48Y103, (3) WS17-234-X46Y99, (4) WS17-207-X17Y99. These four specimens show bifurcated structures at the tops of the processes (blue arrows).

Holotype

Thin section no. Slide 87ZW15-4, CPC27760, from the Pertatataka Formation, Ediacaran successions in Australia (Zhang and Walter, Reference Zang and Walter1992, p. 114, 117, figs. 63D–G, 88).

Description

Small-sized spheroidal vesicle bearing evenly and densely distributed branching processes. These processes consist of conical bases and bifurcate tips, being thin, hollow, and freely communicating with the vesicle interior. Vesicle diameter 34–55 μm (mean 42 μm, N = 11); process length 6–13 μm (mean 10 μm, N = 449); process basal width 2–3 μm (mean 3μm, N = 84); distance between processes 3–5 μm (mean 4 μm, N = 87); ~25–52 processes in circumferential view.

Material

Thirteen specimens from Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area.

Remarks

The specimens are identified as Variomargosphaeridium gracile based on vesicle size and process morphology. Although V. litoschum and V. floridum Nagovitsin and Moczydłowska in Moczydłowska and Nagovitsin, Reference Moczydłowska and Nagovitsin2012 also exhibit branching processes, they are considerably larger in both vesicle and process sizes compared to our specimens (Grey, Reference Grey2005; Moczydłowska and Nagovitsin, Reference Moczydłowska and Nagovitsin2012; Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a). In addition, the processes of V. floridum branch distally to form an apical crown of branchlets, and the branching pattern of V. litoschum is more complex than that of V. gracile (Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a).

Genus Weissiella Vorob'eva, Sergeev, and Knoll, Reference Vorob'eva, Sergeev and Knoll2009, emend. Liu and Moczydłowska, Reference Liu and Moczydłowska2019

Type species

Weissiella grandistella Vorob'eva, Sergeev, and Knoll, Reference Vorob'eva, Sergeev and Knoll2009, emend. Liu and Moczydłowska, Reference Liu and Moczydłowska2019 from the East European Platform and 2605.5 m depth of keltminsk 1 borehole, Ediacaran and Yangtze Gorges area, Doushantuo Formation.

Weissiella cf. W. grandistella Vorob'eva, Sergeev, and Knoll, Reference Vorob'eva, Sergeev and Knoll2009,
emend. Liu and Moczydłowska, Reference Liu and Moczydłowska2019
Figures 2.8, 10

Reference Vorob'eva, Sergeev and Knoll2009

Weissiella grandistella Vorob'eva, Sergeev, and Knoll, p. 183–185, figs. 10.1a–f.

Reference Liu and Moczydłowska2019

Weissiella grandistella; Liu and Moczydłowska, p. 163, figs. 91F, G, 92A–G.

Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021

Weissiella cf. W. grandistella; Ouyang et al., p. 40, 41, fig. 24A–H.

Reference Ye, Li, Tong, An, Hu and Xiao2022

Weissiella cf. W. grandistella; Ye et al., p. 70, fig. 49D–F.

Holotype

Thin section no. 14700-13, from the Ediacara, upper part of Vychegda Formation (Vorob'eva et al., Reference Vorob'eva, Sergeev and Knoll2009, p. 183–185, figs. 10.1a–f).

Description

Medium-sized spheroidal vesicle featuring a few large processes. These processes, hollow and conical, exhibit a rounded or blunt end and have transverse crosswalls that are flat or distally convex. Vesicle diameter 118 μm (from specimen in Fig. 10.1); process length 33 μm (mean 33 μm, N = 4); process basal width 13 μm (mean 13 μm, N = 5); distance between processes 3–5 μm (mean 3 μm, N = 2); ~25–52 processes on vesicle periphery in circumferential view.

Figure 10. Weissiella cf. W. grandistella Vorob'eva, Sergeev, and Knoll, Reference Vorob'eva, Sergeev and Knoll2009, emend. Liu and Moczydłowska, Reference Liu and Moczydłowska2019. Thin section numbers: (1) WS17-2-195-X54Y101. (2–4) Magnified views of (1) showing crosswall structures: (2) red arrow; (3) green arrow; (4) blue arrow.

Material

One specimen from Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area.

Remarks

The specimen exhibits similarities to Weissiella grandistella in terms of process morphology, length, and crosswalls. However, its vesicle diameter is smaller compared to that reported for W. grandistella specimens from the East European Platform (vesicle diameter 450–500 μm). Following the description of W. cf. W. grandistella by Ouyang et al. (Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021) and Ye at al. (Reference Ye, Li, Tong, An, Hu and Xiao2022), we categorize our specimen as W. cf. W. grandistella.

Summary of taxonomy

After examining >500 thin sections of black phosphorite, we discovered numerous acanthomorphic acritarchs, the majority of which belong to LAAs with a diameters > 200 μm. Although we identified several new species of Yinitianzhushania that might have not been reported previously (which will be discussed in a separate paper), most of the specimens can be attributed to previously reported genera. This report specifically delves into SAAs, particularly those with diameters <60 μm (Fig. 11). These diminutive specimens have been infrequently reported by previous researchers in the Weng'an Biota. The abundance of these SAAs is significantly lower than that of LAAs. Due to their smaller size, they are more difficult to detect under the microscope. We discovered >70 specimens of SAAs (< 60 μm in diameter; Fig. 11) and three specimens of MAAs (no more than 150 μm in diameter; Fig. 11).

Figure 11. Measurements for process length (left) and process quantity (right) versus vesicle diameter of acanthomorphic acritarchs in the Weng'an Biota.

Based on detailed observations and microscopic imaging (Fig. 12), we characterized the vesicle morphology and structure of these small and medium-sized acritarchs, including the shape, length, and density of their processes (specific descriptions are in the Systematic paleontology section). Through meticulous morphological comparison, we preliminarily identified seven species from four genera, namely Tanarium conoideum, Tanarium elegans, Tanarium tuberosum, Mengeosphaera membranifera, M. minima, Estrella recta, and Variomargosphaeridium gracile, and one possibly new form tentatively placed in open nomenclature, Weissiella cf. W. grandistella. The abundance of Mengeosphaera and Tanarium specimens was relatively higher, accounting for > 60% of the discovered specimens, whereas the abundance of the other taxa was relatively low. Mengeosphaera was identified by its biform process, whereas Tanarium was identified by its conical process; Estrella by the length of its processes exceeding the vesicle diameter; Variomargosphaeridium by branching hollow processes; and Weissiella by short conical to cylindrical processes with internal crosswalls.

Figure 12. The distribution of the Ediacaran small and medium-sized acanthomorphic acritarchs in the present study (modified from Li et al., Reference Li, Bogdanova, Collins, Davidson, Waele, Ernst, Fitzsimons, Fuck, Gladkochub, Jacobs, Karlstrom, Lu, Natapov, Pease, Pisarevsky, Thrane and Vernikovsky2008).

Tanarium conoideum was previously reported in the Weng'an Biota by an earlier study (Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a). However, the specimens that they reported had a diameter >100 μm, whereas the specimens that we reported for the same species had a diameter of no more than 60 μm. The other SAAs and MAAs from three genera and five species (Estrella recta, Mengeosphaera membranifera, Mengeosphaera minima, Tanarium elegans, and Tanarium tuberosum) mentioned above were discovered for the first time in the Weng'an Biota. These fossils not only provide new materials for reconstructing the composition of the fossil assemblage of the Weng'an Biota, but also offer new evidence for gaining a more comprehensive understanding of the marine ecosystem at that time.

Moreover, these SAAs are not exclusive to the Weng'an Biota. Some common acritarch elements have also been found in the Yangtze Gorges region of South China, Australia, Siberia, and the East European Platform (Fig. 12). For example, Estrella recta and Mengeosphaera bellula were found in both the Weng'an and the Yangtze Gorges region of South China, whereas Tanarium tuberosum was found in the Weng'an and the Yangtze Gorges region of South China, the Easten Officer Basin of South Australia, the Siberian Platform of Russia, and the Timan Ridge of the East European Platform. Tanarium conoideum was found in the Weng'an, the Yangtze Gorges of South China, and the Siberia Platform of Russia. Although their phylogenetic affinities are still disputed, these globally distributed acanthomorphic acritarchs have the potential to be further explored in the subdivision and global/regional correlation of the Ediacaran system.

Implications for biostratigraphic correlation

Given the widespread distribution of these newly discovered acanthomorphic acritarchs in the Weng'an Biota, they have the potential to contribute to stratigraphic division and correlation within the Ediacaran System. In 2014, Liu et al. established two biozones based on acritarch fossil assemblages from the Ediacaran Doushantuo Formation in the Yangtze Gorges area: the lower acritarch biozone, dominated by Tianzhushania spinosa Yin and Li, Reference Yin and Li1978, emend. C. Yin in Yin and Liu, Reference Yin, Liu, Zhao, Xing, Ding, Liu and Zhao1988, and the upper acritarch biozone, dominated by Tanarium conoideum, Hocosphaeridium scaberfacium Zhang in Zhang and Walter, Reference Zang and Walter1992, and Hocosphaeridium anozos (see Liu et al., Reference Liu, Xiao, Yin, Chen, Zhou and Li2014a). Liu and Moczydłowska (Reference Liu and Moczydłowska2019) proposed four new biozones based on the latest fossil data, in ascending order: the Appendisphaera grandis-Weissiella grandistella-Tianzhushania spinosa Assemblage Zone, Tanarium tuberosum-Schizofusa zangwenlongii Assemblage Zone, Tanarium conoideum-Cavaspina basiconica Assemblage Zone, and Tanarium pycnacanthum-Ceratosphaeridium glaberosum Assemblage Zone.

Among the newly discovered SAAs and MAAs in the Weng'an Biota, Tanarium tuberosum from the Yangtze Gorges area belongs to the Tanarium tuberosum-Schizofusa zangwenlongii Assemblage Zone, whereas Tanarium conoideum comes from the Tanarium conoideum-Cavaspina basiconica Assemblage Zone. Considering the presence of Tianzhushania spinosa in the Weng'an Biota, it belongs to the Appendisphaera grandis-Weissiella grandistella-Tianzhushania spinosa Assemblage Zone in the Yangtze Gorges area. In the Doushantuo Formation of the Weng'an area, these taxa mainly come from a < 2 m thick layer of black phosphorite (Unit 4A). This contrasts with the Yangtze Gorges area, where the distribution ranges of acritarchs in the four biozones do not overlap. This situation poses challenges for stratigraphic correlation.

The acritarch fossil assemblage from the Weng'an Biota, as presented in this report, originates from the same stratigraphic horizon, namely Unit 4A of the Doushantuo Formation in the Weng'an area. However, the acritarch fossils of the same genus and species in the Yangtze Gorges area are distributed across three different fossil zones within Member II of the Doushantuo Formation. Several factors could contribute to this discrepancy. We believe that the 2 m thick black phosphorite (Unit 4A) is highly condensed, and the fossils in the Weng'an Biota are not in situ but rather redeposited after undergoing repeated transportation and reworking within the basin (Yin et al., Reference Yin, Liu, Li, Tafforeau and Zhu2014; Bottjer et al., Reference Bottjer, Yin, Zhao and Zhu2020). This might explain why acritarchs that were originally expected to come from three different fossil zones (i.e., different stratigraphic layers) coexist in one 2 m thick stratigraphic layer in the Weng'an area's Doushantuo Formation. Despite this, previous studies have reported 24 genera and 69 species of acritarchs from Member Ⅱ of the Doushantuo Formation at three sections (Jiulongwan, Jinguadun, and Wuzhishan) in the Yangtze Gorges area (Ouyang et al., Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021). Two taxa (Mengeosphaera minima and Weissiella cf. W. grandistella) in this study are consistent with those reported by Ouyang et al. (Reference Ouyang, Zhou, Xiao, Guan, Chen, Yuan and Sun2021). It is recommended to correlate Unit 4A of the Doushantuo Formation containing the Weng'an Biota to the Ediacaran Doushantuo Formation Member Ⅱ in the Yangtze Gorges area using acritarch fossils (Xiao et al., Reference Xiao, Zhou, Liu, Wang and Yuan2014a; Liu and Moczydłowska, Reference Liu and Moczydłowska2019; Ouyang et al., Reference Ouyang, Zhou, Xiao, Chen and Shao2019).

In 2005, Grey identified the Tanarium conoideum-Schizofusa risoria-Variomargosphaeridium litoschum Assemblage Zone in the Australian Ediacaran strata. Some acritarch species from this biozone have also been found in the Weng'an area, including Tanarium conoideum and Variomargosphaeridium litoschum. Consequently, Xiao et al. (Reference Xiao, Zhou, Liu, Wang and Yuan2014a) suggested correlating the stratigraphic level of the Weng'an Biota to the Tanarium conoideum-Schizofusa risoria-Variomargosphaeridium litoschum Assemblage Zone in the Australian Ediacaran System. The new findings in this study are consistent with this perspective. However, considering the co-occurrence of acritarch fossils from different biozones in the same black phosphorite horizon (i.e., Unit 4A of the Doushantuo Formation) in the Weng'an area, it is challenging to separate their distribution ranges in the stratigraphic sequence, and such correlations should be made cautiously. In the future, conducting higher-resolution stratigraphic sampling of acanthomorphic acritarch fossils in the black phosphorite and gray phosphatic dolomite of the Weng'an Doushantuo Formation could contribute to a more comprehensive resolution of this issue.

Conclusion

This study discovered seven species and one possible new form tentatively placed in open nomenclature (Weissiella cf. W. grandistella) of SAAs and MAAs in the Weng'an Biota, including five species reported for the first time in the Weng'an area. Together with the previously reported fossil materials, there are a total of 50 species and one undetermined species of acanthomorphs in the Weng'an Biota (Table 1). Although some of these acritarchs are local species, most of these species have also been found in other regions, e.g., the Yangtze Gorges area (South China), Australia, and Siberia. The presence of so many shared acritarch species among different regions plays a crucial role in the subdivision and correlation of the Ediacaran System. Based on the current data, the acritarch assemblages of the Doushantuo Formation in the Weng'an area share common species with three acritarch assemblage zones (Appendisphaera grandis–Weissiella grandistella–Tianzhushania spinosa Assemblage Zone, Tanarium tuberosum–Schizofusa zangwenlongii Assemblage Zone, and Tanarium conoideum–Cavaspina basiconica Assemblage Zone) from the lower part of Member II of the Ediacaran Doushantuo Formation in the Yangtze Gorges area, as well as the Tanarium conoideum–Schizofusa risoria–Variomargosphaeridium litoschum Assemblage Zone from the Ediacaran Pertatataka Formationin in Australia. This taxonomic similarity indicates a correlation of Unit 4A of the Ediacaran Doushantuo Formation in the Weng'an area, Member II of the Ediacaran Doushantuo Formation in the Yangtze Gorges area, and the upper part of the Ediacaran Pertatataka Formation in Australia.

The fossils reported in this report were collected from the black phosphorites of the Doushantuo Formation in Weng'an. Similar to the chert nodules in the Yangtze Gorges area, the study of acritarchs in black phosphorites can only be conducted through thin sections. Because the information obtained from acritarchs observed in thin sections differs to some extent from the compressed organic acritarchs obtained from shale through acid maceration, achieving consistent taxonomic criteria for acritarchs from different taphonomic windows becomes challenging. This inconsistency somewhat undermines the potential of acritarchs in biostratigraphic subdivision and correlation. Therefore, achieving higher-resolution biostratigraphic correlation of the Ediacaran System in the future not only requires detailed layer-by-layer sampling in different localities, but also needs to overcome the preservation bias and inconsistency in taxonomic criteria for acritarchs from different taphonomic windows by introducing new techniques and methods.

Acknowledgments

This work was supported by the National Natural Science Foundation of China (42022010, 41921002, U2244202). We would like to thank Professor C. Zhou for providing suggestions about schematic drawings, and we thank the guest editor T. Selly. We are also most grateful for the detailed and constructive comments provided by two anonymous referees.

Declaration of competing interests

The authors declare none.

Appendix 1. Measured data of acritarchs in this study.

References

Anderson, R.P., Macdonald, F.A., Jones, D.S., McMahon, S., and Briggs, D.E.G., 2017, Doushantuo-type microfossils from latest Ediacaran phosphorites of northern Mongolia: Geology, v. 45, no. 12, p. 10791082, https://doi.org/10.1130/G39576.1.CrossRefGoogle Scholar
Bottjer, D.J., Yin, Z.J., Zhao, F.C., and Zhu, M.Y., 2020, Comparative taphonomy and phylogenetic signal of phosphatized Weng'an and Kuanchuanpu Biotas: Precambrian Research, v. 349, n. 105408, https://doi.org/10.1016/j.precamres.2019.105408.CrossRefGoogle Scholar
Chen, J.Y., 2004, The Dawn of Animal World: Nanjing, China, Jiangsu Science and Technology Press, 336 p.Google Scholar
Chen, M.E., and Liu, K.W., 1986, The geological significance of newly discovered microfossils from the upper Sinian (Doushantuo age) phosphorites: Scientia Geologica Sinica, v. 1, p. 4653.Google Scholar
Chen, S., Yin, C., Liu, P., Gao, L., Tang, F., and Wang, Z., 2010, Microfossil assemblage from chert nodules of the Ediacaran Doushantuo Formation in Zhangcunping, northern Yichang, South China: Acta Geologica Sinica (Chinese Edition), v. 84, p. 7077. [In Chinese]Google Scholar
Condon, D., Zhu, M., Bowring, S., Wang, W., Yang, A., and Jin, Y., 2005, U-Pb ages from the neoproterozoic Doushantuo Formation, China: Science, v. 308, no. 5718, p. 9598, https://doi.org/10.1126/science.1107765.CrossRefGoogle ScholarPubMed
Cunningham, J., Vargas, K., Yin, Z., Bengtson, S., and Donoghue, P., 2017, The Weng'an biota (Doushantuo Formation): an Ediacaran window on soft-bodied and multicellular microorganisms: Journal of the Geological Society, v. 174, no. 5, p. 793802, https://doi.org/10.1144/jgs2016-142.CrossRefGoogle Scholar
Evitt, W.R., 1963, A discussion and proposals concerning fossil dinoflagellates, hystrichospheres, and acritarchs: Proceedings of the National Academy of Sciences of the United States of America, v. 49, p. 158164, 298–302.CrossRefGoogle ScholarPubMed
Golubkova, E.Y., Raevskaya, E.G., and Kuznetsov, A.B., 2010, Lower Vendian microfossil assemblages of East Siberia: significance for solving regional stratigraphic problems: Stratigraphy and Geological Correlation, v. 18, no. 4, p. 353375, https://doi.org/10.1134/S0869593810040015.CrossRefGoogle Scholar
Grey, K., 2005, Ediacaran Palynology of Australia: Canberra, Association of Australasian Palaeontologists, Memoir 31, 439 p.Google Scholar
Knoll, A.H., 1984, Microbiotas of the late Precambrian Hunnberg Formation, Nordaustlandet, Svalbard: Journal of Paleontology, v. 58, p. 131162.Google Scholar
Knoll, A., 1992, Microfossils in metasedimentary cherts of the Scotia Group, Prins Karls Forland, western Svalbard: Palaeontology, v. 35, p. 751774.Google Scholar
Knoll, A.H., Swett, K., and Mark, J., 1991, Paleobiology of a Neoproterozoic tidal flat/lagoonal complex: the Draken Conglomerate Formation, Spitsbergen: Journal of Paleontology, v. 65, no. 4, p. 531570.10.1017/S0022336000030663CrossRefGoogle ScholarPubMed
Kolosova, S.P., 1991, Late Precambrian spiny microfossils from the eastern part of the Siberian Platform: Algologiya, v. 1, no. 2, p. 5359.Google Scholar
Li, Z.X., Bogdanova, S.V., Collins, A.S., Davidson, A., Waele, B., Ernst, R.E., Fitzsimons, I.C.W., Fuck, R.A., Gladkochub, D.P., Jacobs, J., Karlstrom, K.E., Lu, S., Natapov, L.M., Pease, V., Pisarevsky, S.A., Thrane, K., and Vernikovsky, V., 2008, Assembly, configuration, and break-up history of Rodinia: a synthesis: Precambrian Research, v. 160, p. 179210, https://doi.org/10.1016/j.precamres.2007.04.021.CrossRefGoogle Scholar
Liu, P., and Moczydłowska, M., 2019, Ediacaran microfossils from the Doushantuo Formation chert nodules in the Yangtze Gorges area, South China, and new biozones: Fossils and Strata, v. 65, p. 1172, https://doi.org/10.1002/9781119564225.ch1.CrossRefGoogle Scholar
Liu, P., and Yin, C., 2005, New data of phosphatized acritarchs from the Ediacaran Doushantuo Formation at Weng'an, Guizhou Province, southwest China: Acta Geologica Sinica (English Edition), v. 79, p. 575581.Google Scholar
Liu, P., Yin, C., Chen, S., Tang, F., and Gao, L., 2012, Discovery of Ceratosphaeridium (Acritarcha) from the Ediacaran Doushantuo Formation in Yangtze Gorges, South China and its biostratigraphic implication: Bulletin of Geosciences, v. 87, p. 195200, https://doi.org/10.3140/bull.geosci.1223.CrossRefGoogle Scholar
Liu, P., Xiao, S., Yin, C., Chen, S., Zhou, C., and Li, M., 2014a, Ediacaran acanthomorphic acritarchs and other microfossils from chert nodules of the upper Doushantuo Formation in the Yangtze Gorges area, South China: Journal of Paleontology, v. 88, no. 1, p. 1139, https://doi.org/10.1666/13-009.CrossRefGoogle Scholar
Liu, P., Chen, S., Zhu, M., Li, M., Yin, C., and Shang, X., 2014b, High-resolution biostratigraphic and chemostratigraphic data from the Chenjiayuanzi section of the Doushantuo Formation in the Yangtze Gorges area, South China: implication for subdivision and global correlation of the Ediacaran System: Precambrian Research, v. 249, p. 199214, https://doi.org/10.1016/j.precamres.2014.05.014.CrossRefGoogle Scholar
McFadden, K., Xiao, S., Zhou, C., and Kowalewski, M., 2009, Quantitative evaluation of the biostratigraphic distribution of acanthomorphic acritarchs in the Ediacaran Doushantuo Formation in the Yangtze Gorges area, South China: Precambrian Research, v. 173, nos. 1–4, p. 170190, https://doi.org/10.1016/j.precamres.2009.03.009.CrossRefGoogle Scholar
Moczydłowska, M., 2005, Taxonomic review of some Ediacaran acritarchs from the Siberian Platform: Precambrian Research, v. 136, no. 3/4, p. 283307, https://doi.org/10.1016/j.precamres.2004.12.001.CrossRefGoogle Scholar
Moczydłowska, M., 2015, Algal affinities of Ediacaran and Cambrian organic-walled microfossils with internal reproductive bodies: Tanarium and other morphotypes: Palynology, v. 40, no. 1, p. 83121, https://doi.org/10.1080/01916122.2015.1006341.CrossRefGoogle Scholar
Moczydłowska, M., and Nagovitsin, K., 2012, Ediacaran radiation of organic-walled microbiota recorded in the Ura Formation, Patom Uplift, East Siberia: Precambrian Research, v. 198–199, p. 124, https://doi.org/10.1016/j.precamres.2011.12.010.CrossRefGoogle Scholar
Moczydłowska, M., Vidal, G., and Rudavskaya, V., 1993, Neoproterozoic (Vendian) phytoplankton from the Siberian Platform, Yakutia: Palaeontology, v. 36, no. 3, p. 495521.Google Scholar
Nagovitsyn, K.E., Faizullin, M.S., and Yakshin, M.S., 2004, New forms of Baikalian acanthomorphytes from the Ura Formation of the Patom Uplift, East Siberia: Geologiya e Geofisika, v. 45, p. 719.Google Scholar
Narbonne, G., Xiao, S., and Shields, G., 2012, The Ediacaran Period, in Gradstein, F.M., Ogg, J.G., Schmitz, M.D., et al., eds., The Geologic Time Scale 2012: Boston, Elsevier, p. 413435.CrossRefGoogle Scholar
Ouyang, Q., Zhou, C., Xiao, S., Chen, Z., and Shao, Y., 2019, Acanthomorphic acritarchs from the Ediacaran Doushantuo Formation at Zhangcunping in South China, with implications for the evolution of early Ediacaran eukaryotes: Precambrian Research, v. 320, p. 171192, https://doi.org/10.1016/j.precamres.2018.10.012.CrossRefGoogle Scholar
Ouyang, Q., Zhou, C., Xiao, S., Guan, C., Chen, Z., Yuan, X., and Sun, Y., 2021, Distribution of Ediacaran acanthomorphic acritarchs in the lower Doushantuo Formation of the Yangtze Gorges area, South China: evolutionary and stratigraphic implications: Precambrian Research, v. 353, n. 106005, https://doi.org/10.1016/j.precamres.2020.106005.CrossRefGoogle Scholar
Prasad, B., and Ramson, A., 2016, Record of Ediacaran complex acanthomorphic acritarchs from the lower Vindhyan succession of the Chambal Valley (East Rajasthan), India and their biostratigraphic significance: Journal of the Palaeontological Society of India, v. 61, p. 2962.CrossRefGoogle Scholar
Sergeev, V., Knoll, A., and Vorob'eva, N., 2011, Ediacaran microfossils from the Ura Formation, Baikal-Patom Uplift, Siberia: taxonomy and biostratigraphic significance: Journal of Paleontology, v. 85, no. 5, p. 9871011, https://doi.org/10.1666/11-022.1.CrossRefGoogle Scholar
Shang, X., Liu, P., and Moczydłowska, M., 2019, Acritarchs from the Doushantuo Formation at Liujing section in Songlin area of Guizhou Province, South China: implications for early–middle Ediacaran biostratigraphy: Precambrian Research, v. 334, n. 105453, https://doi.org/10.1016/j.precamres.2019.105453.CrossRefGoogle Scholar
Steiner, M., Li, G., Qian, Y., Zhu, M., and Erdtmann, B.D., 2007, Neoproterozoic to early Cambrian small shelly fossil assemblages and a revised biostratigraphic correlation of the Yangtze Platform (China): Palaeogeography, Palaeoclimatology, Palaeoecology, v. 254, no. 1/2, p. 6799, https://doi.org/10.1016/j.palaeo.2007.03.046.CrossRefGoogle Scholar
Veis, A.F., Vorob'eva, N.G., and Goubkova, E.Y., 2006, The early Vendian microfossils first found in the Russian Plate: taxonomic composition and biostratigraphic significance: Stratigraphy and Geological Correlation, v. 14, p. 368385, https://doi.org/10.1134/S0869593806040022.CrossRefGoogle Scholar
Vidal, G., 1990, Giant acanthomorph acritarchs from the upper Proterozoic in southern Norway: Palaeontology, v. 33, p. 287298.Google Scholar
Vorob'eva, N.G., and Petrov, P.Y., 2020, Microbiota of the Barakun Formation and biostratigraphic characteristics of the Dal'nyaya Taiga Group: early Vendian of the Ura Uplift (eastern Siberia): Stratigraphy and Geological Correlation, v. 28, p. 365380, https://doi.org/10.1134/S0869593820040103.CrossRefGoogle Scholar
Vorob'eva, N.G., Sergeev, V.N., and Chumakov, N.M., 2008, New finds of early Vendian microfossils in the Ura Formation: revision of the Patom Supergroup Age, middle Siberia: Doklady Earth Sciences, v. 419, no. A, p. 411416, https://doi.org/10.1134/S1028334X08030136.CrossRefGoogle Scholar
Vorob'eva, N.G., Sergeev, V.N., and Knoll, A.H., 2009, Neoproterozoic microfossils from the northeastern margin of the East European Platform: Journal of Paleontology, v. 83, no. 2, p. 161196, https://doi.org/10.1666/08-064.1.CrossRefGoogle Scholar
Willman, S., and Moczydłowska, M., 2008, Ediacaran acritarch biota from the Giles 1 drillhole, Officer Basin, Australia, and its potential for biostratigraphic correlation: Precambrian Research, v. 162, no. 3/4, p. 498530, https://doi.org/10.1016/j.precamres.2007.10.010.CrossRefGoogle Scholar
Willman, S., and Moczydłowska, M., 2011, Acritarchs in the Ediacaran of Australia—local or global significance? Evidence from the Lake Maurice West 1 drillcore: Review of Palaeobotany and Palynology, v. 166, no. 1/2, p. 1228, https://doi.org/10.1016/j.revpalbo.2011.04.005.CrossRefGoogle Scholar
Willman, S., Moczydłowska, M., and Grey, K., 2006, Neoproterozoic (Ediacaran) diversification of acritarchs—a new record from the Murnaroo 1 drillcore, eastern Officer Basin, Australia: Review of Palaeobotany and Palynology, v. 139, no. 1–4, p. 1739, https://doi.org/10.1016/j.revpalbo.2005.07.014.CrossRefGoogle Scholar
Xiao, S., 2004, New multicellular algal fossils and acritarchs in Doushantuo chert nodules (Neoproterozoic, Yangtze Gorges, South China): Journal of Paleontology, v. 78, p. 393401, https://doi.org/10.1666/0022-3360(2004)078<0393:NMAFAA>2.0.CO;2.2.0.CO;2>CrossRefGoogle Scholar
Xiao, S., and Knoll, A., 1999, Fossil preservation in the Neoproterozoic Doushantuo phosphorite Lagerstätte, South China: Lethaia, v. 32, p. 219240.CrossRefGoogle ScholarPubMed
Xiao, S., and Knoll, A., 2000, Phosphatized animal embryos from the Neoproterozoic Doushantuo Formation at Weng'an, Guizhou, South China: Journal of Paleontology, v. 74, no. 5, p. 767788, https://doi.org/10.1666/0022-3360(2000)074<0767:PAEFTN>2.0.CO;2.2.0.CO;2>CrossRefGoogle Scholar
Xiao, S., and Knoll, A.H., 2007, Fossil preservation in the Neoproterozoic Doushantuo phosphorite Lagerstatte, South China: Lethaia, v. 32, p. 219238, https://doi.org/10.1111/j.1502-3931.1999.tb00541.x.CrossRefGoogle Scholar
Xiao, S., and Narbonne, G., 2020, The Ediacaran Period in geologic time, in Gradstein, F.M., Ogg, J.G., Schmitz, M.D., and Ogg, G.M., eds., The Geologic Time Scale 2020: Boston, Elsevier, p. 521561.CrossRefGoogle Scholar
Xiao, S., Zhang, Y., and Knoll, A., 1998, Three-dimensional preservation of algae and animal embryos in a Neoproterozoic phosphorite: Nature, v. 391, no. 6667, p. 553558.10.1038/35318CrossRefGoogle Scholar
Xiao, S., Knoll, A., Zhang, L., and Hua, H., 1999, The discovery of Wengania globosa in Doushantuo phosphorites in Chadian, Shaanxi Province: Acta Micropalaeontologica Sinica, v. 16, p. 259266.Google Scholar
Xiao, S., Schiffbauer, J., McFadden, K., and Hunter, J., 2010, Petrographic and SIMS pyrite sulfur isotope analyses of Ediacaran chert nodules: implications for microbial processes in pyrite rim formation, silicification, and exceptional fossil preservation: Earth and Planetary Science Letters, v. 297, no. 3/4, p. 481495, https://doi.org/10.1016/j.epsl.2010.07.001.CrossRefGoogle Scholar
Xiao, S., Zhou, C., Liu, P., Wang, D., and Yuan, X., 2014a, Phosphatized acanthomorphic acritarchs and related microfossils from the Ediacaran Doushantuo Formation at Weng'an (South China) and their implications for biostratigraphic correlation: Journal of Paleontology, v. 88, no. 1, p. 167, https://doi.org/10.1666/12-157R.CrossRefGoogle Scholar
Xiao, S., Muscente, A., Chen, L., Zhou, C., Schiffbauer, J., Wood, A., Polys, N., and Yuan, X., 2014b, The Weng'an biota and the Ediacaran radiation of multicellular eukaryotes: National Science Review, v. 1, no. 4, p. 498520, https://doi.org/10.1093/nsr/nwu061.CrossRefGoogle Scholar
Xie, G., Zhou, C., Mcfadden, K.A., Xiao, S., and Yuan, X., 2008, Microfossils discovered from the Sinian Doushantuo Formation in the Jiulongwan section, East Yangtze Gorges area, Hubei Province, South China: Acta Palaeontologica Sinica, v. 47, p. 279291.Google Scholar
Yang, L., Pang, K., Chen, L., Zhong, Z., and Yang, F., 2020, New materials of microfossils from the Ediacaran Doushantuo Formation in Baizhu phosphorite deposit, Baokang, Hubei Provience [sic]: Acta Micropalaeontologica Sinica, v. 37, no. 1, p. 120.Google Scholar
Yang, C., Rooney, A., Condon, D., Li, X., Grazhdankin, D., Bowyer, F., Hu, C., Macdonald, F.A., and Zhu, M., 2021, The tempo of Ediacaran evolution: Science Adances, v. 7, no. 45, n. 9643, https://doi.org/10.1126/sciadv.abi9643.Google ScholarPubMed
Ye, Q., Li, J., Tong, J., An, Z., Hu, J., and Xiao, S., 2022, A microfossil assemblage from the Ediacaran Doushantuo Formation in the Shennongjia area (Hubei Province, South China): filling critical paleoenvironmental and biostratigraphic gaps: Precambrian Research, v. 377, n. 106691, https://doi.org/10.1016/j.precamres.2022.106691.CrossRefGoogle Scholar
Yin, C., 1990, Spinose acritarchs from the Toushantuo Formation and its geological significance: Acta Micropalaeontologica Sinica, v. 7, p. 265270.Google Scholar
Yin, C., and Liu, G., 1988, Micropaleofloras, in Zhao, Z., Xing, Y., Ding, Q., Liu, G., Zhao, Y., et al., eds., The Sinian System of Hubei: Wuhan, China University of Geosciences Press, p. 170180.Google Scholar
Yin, C., Liu, P., Awramik, S.M., Chen, S., Tang, F., Gao, L., Wang, Z., and Riedman, L.A., 2011, Acanthomorph biostratigraphic succession of the Ediacaran Doushantuo Formation in the East Yangtze Gorges, South China: Acta Geologica Sinica (English Edition), v. 85, p. 283295, https://doi.org/10.1111/j.1755-6724.2011.00398.x.CrossRefGoogle Scholar
Yin, L., 1987, Microbiotas of latest Precambrian sequences in China, in Nanjing Institute of Geology and Palaeontology Academica Sinica, ed., Stratigraphy and Palaeontology of Systemic Boundaries in China: Precambrian-Cambrian Boundary (1): Nanjing, China, Nanjing University Press, p. 415– 494.Google Scholar
Yin, L., and Li, Z., 1978, Precambrian microfloras of southwest China with reference to their stratigraphic significance: Memoir, Nanjing Institute of Geology and Palaeontology, Academia Sinica, v. 10, p. 41108.Google Scholar
Yin, L., Zhu, M., Knoll, A., Yuan, X., Zhang, J. and Hu, J., 2007, Doushantuo embryos preserved inside diapause egg cysts: Nature, v. 446, p. 661663, https://doi.org/10.1038/nature05682.CrossRefGoogle ScholarPubMed
Yin, L., Zhou, C., and Yuan, X., 2008, New data on Tianzhushania—an Ediacaran diapause egg cyst from Yichang, Hubei: Acta Palaeontologica Sinica, v. 47, p. 129140.Google Scholar
Yin, L., Wang, D., Yuan, X., and Zhou, C., 2011, Diverse small spinose acritarchs from the Ediacaran Doushantuo Formation, South China: Palaeoworld, v. 20, no. 4, p. 279289, https://doi.org/10.1016/j.palwor.2011.10.002.CrossRefGoogle Scholar
Yin, Z., Zhu, M., Tafforeau, P., Chen, J., Liu, P., and Li, G., 2013, Early embryogenesis of potential bilaterian animals with polar lobe formation from the Ediacaran Weng'an Biota, South China: Precambrian Research, v. 225, p. 4457, https://doi.org/10.1016/j.precamres.2011.08.011.CrossRefGoogle Scholar
Yin, Z., Liu, P., Li, G., Tafforeau, P., and Zhu, M., 2014, Biological and taphonomic implications of Ediacaran fossil embryos undergoing cytokinesis: Gondwana Research, v. 25, no. 3, p. 10191026, https://doi.org/10.1016/j.gr.2013.01.008.CrossRefGoogle Scholar
Yin, Z., Zhu, M., Davidson, E.H., Bottjer, D.J., Zhao, F., and Tafforeau, P., 2015, Sponge grade body fossil with cellular resolution dating 60 Myr before the Cambrian: Proceedings of the National Academy of Sciences, v. 112, no. 12, p. E1453E1460, https://doi.org/10.1073/pnas.1414577112.CrossRefGoogle ScholarPubMed
Yuan, X., and Hofmann, H.J., 1998, New microfossils from the Neoproterozoic (Sinian) Doushantuo Formation, Weng'an, Guizhou Province, southwestern China: Alcheringa, v. 22, p. 189222.CrossRefGoogle Scholar
Yuan, X., Xiao, S., Yin, L., Knoll, A., Zhou, C., and Mu, X., 2002, Doushantuo Fossils: Life on the Eve of Animal Radiation: Hefei, China, China University of Science and Technology Press, 171 p. [In Chinese, with English summary]Google Scholar
Zang, W., and Walter, M.R., 1992, Late Proterozoic and Cambrian microfossils and biostratigraphy, Amadeus Basin, central Australia: The Association of Australasia Palaeontologists Memoir, v. 12, p. 1132.Google Scholar
Zhang, Y., Yin, L., Xiao, S., and Knoll, A., 1998, Permineralized fossils from the terminal Proterozoic Doushantuo Formation, South China: Journal of Paleontology Memoir, v. 72, supplement, p. 152.CrossRefGoogle Scholar
Zhou, C., Brasier, M., and Xue, Y., 2001, Three-dimensional phosphatic preservation of giant acritarchs from the terminal Proterozoic Doushantuo Formation in Guizhou and Hubei provinces, South China: Palaeontology, v. 44, p. 11571178, https://doi.org/10.1111/1475-4983.00219.Google Scholar
Zhou, C., Chen, Z., and Xue, Y., 2002a, New microfossils from the late Neoproterozoic Doushantuo Formation at Chaoyang phosphorite deposit in Jiangxi Province, South China: Acta Palaeontologica Sinica, v. 41, p. 178192.Google Scholar
Zhou, C., Yuan, X., and Xiao, S., 2002b, Phosphatized biotas from the Neoproterozoic Doushantuo Formation on the Yangtze Platform: Chinese Science Bulletin, v. 47, p. 19181924, https://doi.org/10.1360/02tb9419.CrossRefGoogle Scholar
Zhou, C., Yuan, X., Xiao, S., Chen, Z., and Xue, Y., 2004, Phosphatized fossil assemblage from the Doushantuo Formation in Baokang, Hubei Province: Acta Micropalaeontologica Sinica, v. 21, p. 349366.Google Scholar
Zhou, C., Xie, G., Mcfadden, K., Xiao, S., and Yuan, X., 2007, The diversification and extinction of Doushantuo-Pertatataka acritarchs in South China: causes and biostratigraphic significance: Geological Journal, v. 42, p. 229262, https://doi.org/10.1002/gj.1062.Google Scholar
Zhou, C., Li, X.-H., Xiao, S., Lan, Z., Ouyang, Q., Guan, C., and Chen, Z., 2017, A new SIMS zircon U-Pb date from the Ediacaran Doushantuo Formation: age constraint on the Weng'an biota: Geological Magazine, v. 154, no. 6, p. 11931201, https://doi.org/10.1017/S0016756816001175.CrossRefGoogle Scholar
Zhou, C., Yuan, X., Xiao, S., Chen, Z., and Hua, H., 2019, Ediacaran integrative stratigraphy and timescale of China: Science China-Earth Sciences, v. 62, no. 1, p. 724, https://doi.org/10.1007/s11430-017-9216-2.CrossRefGoogle Scholar
Zhu, M., Zhang, J., and Yang, A., 2007, Integrated Ediacaran (Sinian) chronostratigraphy of South China: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 254, no. 1/2, p. 761, https://doi.org/10.1016/j.palaeo/2007.03.025.CrossRefGoogle Scholar
Zhu, M., Lu, M., Zhang, J., Zhao, F., Li, G., Aihua, Y., Zhao, X., and Zhao, M., 2013, Carbon isotope chemostratigraphy and sedimentary facies evolution of the Ediacaran Doushantuo Formation in western Hubei, South China: Precambrian Research, v. 225, p. 728, https://doi.org/10.1016/j.precamres.2011.07.019.CrossRefGoogle Scholar
Zhu, M., Yang, A., Yuan, J., Li, G., Zhang, J., Zhao, F., Ahn, S., and Miao, L., 2019, Cambrian integrative stratigraphy and timescale of China: Science China Earth Sciences, v. 62, p. 2560, https://doi.org/10.1007/s11430-017-9291-0.CrossRefGoogle Scholar
Figure 0

Table 1. Small and medium-sized acanthomorphs from the Doushantuo Formation in the Weng'an area, records from the published literature and this study. EEP = East European Platform; 1 = Chen, 2004; 2 = Chen and Liu, 1986; 3 = Chen et al., 2010; 4 = Golubkova et al., 2010; 5 = Grey, 2005; 6 = Knoll, 1992; 7 = Kolosova, 1991; 8 = Liu et al., 2012; 9 = Liu et al., 2014a; 10 = Liu and Moczydłowska, 2019; 11 = Moczydłowska, 2005; 12 = Moczydłowska and Nagovitsin, 2012; 13 = Moczydłowska et al., 1993; 14 = Nagovitsin et al., 2004; 15 = Sergeev et al., 2011; 16 = Veis et al., 2006; 17 = Vorob'eva et al., 2009; 18 = Vorob'eva et al., 2008; 19 = Willman and Moczydłowska, 2008; 20 = Willman and Moczydłowska, 2011; 21 = Xiao, 2004; 22 = Xiao et al., 2014a; 23 = Xiao and Knoll, 1999; 24 = Xiao et al., 1999; 25 = Xie et al., 2008; 26 = Yin, 1987; 27 = Yin, 1990; 28 = Yin and Li, 1978; 29 = C. Yin et al., 2011; 30 = Yin et al., 2007; 31 = L. Yin et al., 2011; 32 = Yin et al., 2013; 33 = Yuan and Hofmann, 1998; 34 = Yuan et al., 2002; 35 = Zang and Walter, 1992; 36 = Zhang et al., 1998; 37 = Zhou et al., 2001; 38 = Zhou et al., 2002a; 39 = Zhou et al., 2007; 40 = Zhou et al., 2002b; 41 = Zhou et al., 2004; 42 = Shang et al., 2019; 43 = Ouyang et al., 2021; * = diameter < 100 μm; ** = medium-sized acritarchs reported by this study; # = species reported previously with diameter <100μm.

Figure 1

Figure 1. The geological setting of Weng'an area. (1) Relationships between the Yangtze Block (YB), North China Block (NCB), and Tarim Block (TB). A red star marks the locality of the Weng'an phoshorite mining area. (2) Geological setting of the Weng'an area; the outcrop is marked by a red star. (3) Ediacaran stratigraphic column of the Beidoushan section in the Weng'an area showing the fossil horizon. Modified from Yin et al., 2015.

Figure 2

Figure 2. Schematic drawings of acritarchs: (1) Estrella recta Liu and Moczydłowska, 2019; (2) Mengeosphaera membranifera Shang, Liu, and Moczydłowska, 2019; (3) M. minima Liu et al., 2014a; (4) Tanarium conoideum Kolosova, 1991; (5) Tanarium elegans Liu et al., 2014a; (6) Tanarium tuberosum Moczydłowska, Vidal, and Rudavskaya, 1993, emend. Moczydłowska, 2015; (7) Variomargosphaeridium gracile Xiao et al., 2014a; (8) Weissiella cf. W. grandistella Vorob'eva, Sergeev, and Knoll, 2009, emend. Liu and Moczydłowska, 2019. The left scale bar is for (6) and (8); the right scale bar is for the others.

Figure 3

Figure 3. Estrella recta Liu and Moczydłowska, 2019. Thin section numbers: (1) WS17-225-X42Y105, (2) WS17-225-X46Y106, (3) WS17-195-X54Y99, (4) WS17-157-X64Y101, (5) WS17-259-X19.5Y113, (6) WS17-211-X35Y94.

Figure 4

Figure 4. Mengeosphaera membranifera Shang, Liu, and Moczydłowska, 2019. Thin section numbers: (1) WS17-152-X62Y103, (2) WS17-231-X64Y108, (3) WS17-231-X27Y101, (4) WS17-204-X37Y93, (5) WS17-207-X30Y104, with green arrow indicating site of (6), (6) magnified view of (5).

Figure 5

Figure 5. Mengeosphaera minima Liu et al., 2014a. Thin section numbers: (1) WS17-217-X48Y101, (2) WS17-153-X31Y91, (3) WS17-227-x57y97, (4) WS17-227-X46Y99, (5) WS17-231-X58Y112, (6) WS17-145-X50Y98.

Figure 6

Figure 6. Mengeosphaera minima Liu et al., 2014a. Thin section numbers: (1) WS17-224-X45Y110, (2) WS17-235-X59Y107, (3) WS17-207-x17y99, (4) WS17-256-X36Y114, (5) WS17-220-X38Y100, (6) WS17-219-X25Y101. (1, 2) showing the multicellular structures within their vesicle (blue arrows).

Figure 7

Figure 7. Tanarium conoideum Kolosova, 1991, emend. Moczydłowska et al., 1993. Thin section numbers: (1) WS17-210-X38Y103, (2) WS17-150-X47Y101, (3) WS17-234-X46Y99, (4) WS17-206-X25Y104, (5) WS17-208-X48Y98, (6) WS17-150-X50Y111.

Figure 8

Figure 8. (1, 2) Tanarium elegans Liu et al., 2014a and (3, 4) Tanarium tuberosum Moczydłowska, Vidal, and Rudavskaya, 1993, emend. Moczydłowska, 2015. Thin section numbers: (1) WS17-196-X40Y107, (2) WS17-150-X59.5Y108, (3) WS17-201-x42.5y93.5, (4) WS17-202-X57Y93.

Figure 9

Figure 9. Variomargosphaeridium gracile Xiao et al., 2014a. Thin section numbers: (1) WS17-150-X50Y110, (2) WS17-161-X48Y103, (3) WS17-234-X46Y99, (4) WS17-207-X17Y99. These four specimens show bifurcated structures at the tops of the processes (blue arrows).

Figure 10

Figure 10. Weissiella cf. W. grandistella Vorob'eva, Sergeev, and Knoll, 2009, emend. Liu and Moczydłowska, 2019. Thin section numbers: (1) WS17-2-195-X54Y101. (2–4) Magnified views of (1) showing crosswall structures: (2) red arrow; (3) green arrow; (4) blue arrow.

Figure 11

Figure 11. Measurements for process length (left) and process quantity (right) versus vesicle diameter of acanthomorphic acritarchs in the Weng'an Biota.

Figure 12

Figure 12. The distribution of the Ediacaran small and medium-sized acanthomorphic acritarchs in the present study (modified from Li et al., 2008).