Hostname: page-component-6766d58669-76mfw Total loading time: 0 Render date: 2026-05-20T08:21:13.045Z Has data issue: false hasContentIssue false
  • English
  • Français

The latest encrinurid trilobites from the Lower Devonian of Xinjiang, Northwest China

Published online by Cambridge University Press:  09 October 2023

Juan Ma ,
Jiayi Yin ,
Yilong Liu ,
Xiaoqi Du ,
Shibo Liu  and
Ruiwen Zong Open the ORCID record for Ruiwen Zong [Opens in a new window]
Juan Ma
Affiliation:
State Key Laboratory of Biogeology and Environmental Geology, China University of Geosciences, Wuhan, China
Jiayi Yin
Affiliation:
School of Earth Science, China University of Geosciences, Wuhan, China
Yilong Liu
Affiliation:
School of Earth Science, China University of Geosciences, Wuhan, China
Xiaoqi Du
Affiliation:
School of Earth Science, China University of Geosciences, Wuhan, China
Shibo Liu
Affiliation:
School of Earth Science, China University of Geosciences, Wuhan, China
Ruiwen Zong*
Affiliation:
State Key Laboratory of Biogeology and Environmental Geology, China University of Geosciences, Wuhan, China
*
Corresponding author: Ruiwen Zong; Email: zongruiwen@cug.edu.cn
Rights & Permissions [Opens in a new window]

Abstract

Encrinurids are common in Ordovician and Silurian strata but whether they survived into the Early Devonian is still controversial. This paper documents the encrinurid Batocara sp. near the Silurian–Devonian boundary in western Junggar, Xinjiang. The highest horizon of Batocara sp. is located above the first appearance datum of the Devonian conodont Caudicriodus, confirming that encrinurids may cross the Silurian–Devonian boundary. The presence of Caudicriodus angustoides bidentatus, Zieglerodina planilingu and plate-type loboliths of scyphocrinoids above the highest horizon of Batocara sp. indicates that encrinurids here extend only into the lower part of the first conodont zone of the Lochkovian (i.e., Caudicriodus hesperius Biozone). Encrinurids are widely distributed and easily recognized, and unlike graptolites and conodonts are not controlled by lithofacies. Therefore, it might be possible to use the highest horizon of encrinurids as indicator fossils to identify the approximate position of the Silurian–Devonian boundary in areas or sections where graptolites and conodonts are not present, and at least in northwest China.

Keywords

conodontsEncrinurinaeLochkovianSilurian–Devonian boundarywestern Junggar

Information

Type
Original Article
Information
Geological Magazine , Volume 160 , Issue 8 , August 2023 , pp. 1578 - 1585
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 (http://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), 2023. Published by Cambridge University Press

1. Introduction

Encrinurinae (Encrinuridae, Phacopida) is a cosmopolitan trilobite subfamily that has been reported from North and South America, Europe, Asia, Australia and the Arctic region (see, Temple & Tripp, Reference Temple and Tripp1979; Temple & Wu, Reference Temple and Wu1990). Encrinurinae first appeared in the early Floian or late Tremadocian of the Early Ordovician (Pärnaste, Reference Pärnaste2006) and reached their maximum diversity in the Silurian when they were a major component of the trilobite fauna (Bault et al. Reference Bault, Balseiro, Monnet and Crônier2022). However, the time when encrinurids disappeared is still controversial and inconclusive. Most scholars believe that encrinurids became extinct to the end of Silurian (Ormiston, Reference Ormiston1977; Boucot, Reference Boucot1985; Chlupác, Reference Chlupáč1994), so they were used to determine the Silurian–Devonian boundary (SDB). Nevertheless, some reports suggest that encrinurids can survive into the Devonian (Maksimova et al. Reference Maksimova, Modzhalevskaya, Kaplun and Senkevich1973; Fletcher, Reference Fletcher1975; Biske et al. Reference Biske, Gorianov and Rzonsnickaja1977; Bourque & Lesperance, Reference Bourque and Lesperance1977; Nikiforova, Reference Nikiforova1977; Maksimova, Reference Maksimova1980; Strusz, Reference Strusz1980; Zhang, Reference Zhang1983; Owens et al. Reference Owens, Ivanova, Kim, Popov and Feist2010). But these so-called ‘earliest Devonian encrinurids’ were not age constrained by index graptolites or conodonts, and do not have an undoubted earliest Devonian age. Here, we document encrinurids preserved with earliest Devonian conodonts from western Junggar, Xinjiang, NW China, which provides sufficient evidence for the survival of encrinurids into the Early Devonian. On this basis, the implications of encrinurids for determining the position of the Silurian–Devonian boundary are discussed.

2. Geological setting and materials

Western Junggar is an important part of the Central Asian Orogenic Belt, occupied by Paleozoic accretionary complexes in the south and volcanic arcs in the north (Windley et al. Reference Windley, Alexeiev, Xiao, Kröner and Badarch2007; Xiao et al. Reference Xiao, Han, Yuan, Sun, Lin, Chen, Li, Li and Sun2008; Chen et al. Reference Chen, Han, Ji, Zhang, Xu, He and Wang2010). The well-exposed SDB occurs in strata of the Boshchekul-Chingiz volcanic arc (Hou et al. Reference Hou, Xiang, Lai and Lin1979; Wang, Reference Wang1991; Xiao et al. Reference Xiao, Wu, Wang, Wang and Hou1991, Reference Xiao, Hou, Wu, Liu, Wang, Wang, Cai, Gong, Yan and Cui1992; Zeng & Xiao, Reference Zeng and Xiao1991; Cai et al. Reference Cai, Dou and Edwards1993; Ni et al. Reference Ni, Lenz and Chen1998; Zong & Gong, Reference Zong and Gong2020). The strata near the SDB mainly consist of pyroclastic rocks with a few carbonate rocks (Gong & Zong, Reference Gong and Zong2015), named the Wutubulake and Mangeer formations in ascending order (also referred to as the Wutubulake Member of the Kekexiongkuduke Formation and the Mangeer Member of the Hoboksar Formation, Cai, Reference Cai1999). Both formations yield abundant benthic animal fossils such as corals, brachiopods, trilobites, crinoids and bryozoans (Zeng & Xiao, Reference Zeng and Xiao1991; Xiao et al. Reference Xiao, Hou, Wu, Liu, Wang, Wang, Cai, Gong, Yan and Cui1992; Zong & Gong, Reference Zong and Gong2020). In addition, rich plants and a few graptolites are also found in the Wutubulake Formation (Cai et al. Reference Cai, Dou and Edwards1993; Ni et al. Reference Ni, Lenz and Chen1998). In the past, based on a few studies of graptolites and benthic animals, the ages of the Wutubulake and Mangeer formations were generally considered as Pridoli and Early Devonian, respectively (Cai et al. Reference Cai, Dou and Edwards1993; Ni et al. Reference Ni, Lenz and Chen1998; Cai, Reference Cai1999).

Material for the present study was collected from the upper part of the Wutubulake Formation to the base of the Mangeer Formation in the Mangkelu II section in the northern part of western Junggar (Fig. 1). This section was first reported by Zong and Gong (Reference Zong and Gong2020) who placed the boundary between the Wutubulake Formation and the overing Mangeer Formation between bed 12 and bed 13; however, we make a minor revision to the lithostratigraphic subdivision, moving the boundary between two formations down to between bed 7 and bed 8 (Figs. 1d, 2a–c). The Wutubulake Formation consists generally of fine-grained pyroclastic rocks in turbidite facies, intercalated with thick-bedded coarse-grained pyroclastic rocks and a small amount of calcareous siltstone, with bioclastic or sandy limestone lenses (or thin layers) in the upper part (Fig. 2d–h). The coarse pyroclastic rocks contain allochthonous corals, brachiopods, crinoid stems and trilobites (Fig. 2f, g), and the fine pyroclastic rocks contain rare plants and graptolites. The lower part of the Mangeer Formation consists of coarse pyroclastic rocks, commonly intercalated with thin-bedded calcareous sandstone and bioclastic limestone, yielding corals, brachiopods, trilobites, gastropods, echinoderms and cephalopods, and two layers with plate-type loboliths (Fig. 2i, j; Zong & Gong, Reference Zong and Gong2020). In the upper part of the Mangeer Formation, the granularity of the pyroclastic rocks is slightly finer and the calcium content is increased, with bioclastic limestone and sandy limestone thicker and more abundant and reef limestone formed locally. Therefore, a regressive sequence is formed from the Wutubulake Formation to the Mangeer Formation. The Silurian–Devonian boundary of this section was provisionally located in bed 8 according to a preliminary study of trilobites and plate-type loboliths (Zong & Gong, Reference Zong and Gong2020). However, based on our new conodont data, the SDB needs to be moved down to at least bed 7.

Figure 1.

Geological background and location map of the study area. (a), Paleogeographical location of western Junggar in the Silurian–Devonian transition (modified from Scotese, Reference Scotese2021). (b), (c), Location of the Mangkelu II section and the geological map of study area (modified from Zong & Gong, Reference Zong and Gong2020). (d), Stratigraphic column of Mangkelu II section. Abbreviations: WJ, western Junggar, Kz., Kazakhstan, PAO, Paleo-Asian Ocean, Au., Australia.

Figure 2.

Lithological features and fossils near the Silurian–Devonian boundary of Mangkelu II section in western Junggar, Xinjiang. (a), The stratigraphic division of the Mangkelu II section and the levels of trilobites (red arrows) and important conodonts (blue arrows). (b), (c), The boundary between the Wutubulake Formation and the overlying Mangeer Formation is located between bed 7 and bed 8, Fig. c shows the local amplification of Fig. b. (d), Calcareous siltstone lens in tuffaceous medium sandstone in bed 7-4 of the Wutubulake Formation. (e), Tuffaceous siltstone in bed 7-2 of the Wutubulake Formation. (f), Tuffaceous pebbly coarse sandstone containing crinoid stems in bed 6-3 of the Wutubulake Formation. (g), Tuffaceous medium-coarse sandstone containing encrinurids pygidium at the bottom of bed 7-1 of the Wutubulake Formation. (h), Bioclastic limestone interlayer in bed 7-5 of the Wutubulake Formation. (i), (j), Plate-type lobolith of scyphocrinoid in bed 8-3 of the Mangeer Formation.

All specimens are stored in the State Key Laboratory of Biogeology and Environmental Geology, China University of Geosciences.

3. Results

Near the SDB, encrinurids were found in seven beds, namely bed 6-3 (15.5 m), bed 7-1 (27.4 m), bed 7-4 (62 m), bed 7-4 (65 m), bed 7-4 (69.5 m), bed 7-5 (74.5 m) and bed 8-2 (77.9 m), preserved in bioclastic limestone (Fig. 3a–c), tuffaceous sandstone and pebbly coarse sandstone (Fig. 3d–j). The specimens include cranidia, free cheeks, thoracic segments and pygidia, with pygidia being the most common; no articulated exoskeletons were found. Occurring with the encrinurids are crinoid stem, bryozoan, brachiopod and coral fragments. These encrinurids are relatively uniform in size and are mostly worn on the surface, suggesting allochthonous burial. Based on the non-mucronate pygidium, the wide pygidial pleura and the narrow pygidial axis, as well as the number of pygidial axial rings and pleural ribs, we assign these encrinurids to Batocara Strusz, Reference Strusz1980. It is not possible to identify the specimens at species level due to the poor preservation and lack of adequate and complete cranidia.

Figure 3.

Encrinurid trilobite Batocara sp. from the Wutubulake and Mangeer formations (near the Silurian-Devonian boundary) of Mangkelu II section, western Junggar, Xinjiang. (a)–(c), pygidium, BGEG-MII/T007, bed 7-5 (74.5 m), dorsal view (a), left lateral view (b), and posterior view (c). (d), Incomplete cranidium, BGEG-MII/T010, bed 7-4 (69.5 m), dorsal view. (e)–(f), Complete pygidia, BGEG-MII/T004, BGEG-MII/T015, bed 7-4 (62 m), bed 8-2 (77.9 m), dorsal view. (g)–(j), Incomplete pygidia, BGEG-MII/T012, BGEG-MII/T006, BGEG-MII/T013, BGEG-MII/T011, bed 7-4 (62 m), bed 7-4 (62 m), bed 8-2 (77.9 m), bed 7-4 (69.5 m), dorsal view, and (h) is an internal mold.

Fifteen conodont samples were collected from limestone and calcareous siltstone interlayers or lenses in this section (Fig. 1d), and conodonts were found in all samples except for five horizons, namely bed 6-3 (22.5 m), bed 7-2 (52 m), bed 7-3 (55.5 m), bed 7-4(69.9 m) and bed 7-5 (73 m). However, the conodonts in most samples were broken and could not be identified, and elements with important stratigraphic value were scarce. There are only three samples having age-indicative conodonts, i.e., Caudicriodus sp. from bed 7-4 (72.1 m), Caudicriodus angustoides bidentatus from bed 7-5 (74.5 m) and Caudicriodus angustoides bidentatus and Zieglerodina planilingua from bed 8-3 (82.5 m) (Fig. 4).

Figure 4.

The earliest Devonian conodonts from Mangkelu II section in western Junggar, NW Xinjiang. (a)–(c), Caudicriodus sp., BGEG-MII/C/72.1/001, upper, lateral, and lower views of the I element, Bed 7-4 (72.1 m). (d)–(i), Caudicriodus angustoides bidentatus, BGEG-MII/C/74.5/018, BGEG-MII/C/74.5/019, upper, lateral, and lower views of the I element, Bed 7-5 (74.5 m). (j)–(l), Caudicriodus angustoides bidentatus, BGEG-MII/C/82.5/006, upper, lateral, and lower views of the I element, Bed 8-3 (82.5 m). (m)–(r), Zieglerodina planilingua, BGEG-MII/C/82.5/007, BGEG-MII/C/82.5/008, upper, lateral, and lower views of the P elements, Bed 8-3 (82.5 m).

4. Discussion

4.a. Evidence for Early Devonian encrinurids

The strata containing encrinurids near the SDB are classified as Silurian by most scholars (e.g., Chlupáč et al. Reference Chlupáč, Jaeger and Zikmundova1972; Holloway & Neil, Reference Holloway and Neil1982; Liao et al. Reference Liao, Rong, Hu, Peng and Li1995; Duan & An, Reference Duan and An2004; Zhang & Sun, Reference Zhang and Sun2007). However, some scholars suggesting that a few encrinurids crossed the SDB. There are scattered reports of Early Devonian encrinurids in some areas since the 1970s, such as Tien-Shan in central Aisa (Biske et al. Reference Biske, Gorianov and Rzonsnickaja1977), Podolia in Ukraine (Nikiforova, Reference Nikiforova1977), Central Kazakhstan (Maksimova, Reference Maksimova1975), Québec in Canada (Bourque & Lesperance, Reference Bourque and Lesperance1977) and New South Wales in Australia (Fletcher, Reference Fletcher1975). Unfortunately, the Early Devonian age claimed for these encrinurids was based either on benthic organisms, or on graptolites or conodonts not belonging to index species. Whether these occurrences are all of Early Devonian age is doubtful (Liao et al. Reference Liao, Rong, Hu, Peng and Li1995) and some occurrences regarded as earliest Devonian have been revised by subsequent studies (Liao et al. Reference Liao, Rong, Hu, Peng and Li1995; Zhang & Sun, Reference Zhang and Sun2007). For example, the supposed Early Devonian Encrinurus sp. from Tien-Shan occurs in the same horizon as the conodont Ozarkodina steinhornensis praeoptima (Biske et al. Reference Biske, Gorianov and Rzonsnickaja1977), but using the species of the Ozarkodina eosteinhornensis-steinhornensis group (now Zieglerodina) to define the Silurian–Devonian boundary is considered unreliable (Barrick et al. Reference Barrick, Sundgren and Mcadams2021). The supposed Early Devonian encrinurids from Podolia are from the Tajna Beds, the base of which was once considered to coincide with the Silurian–Devonian boundary. However, that position for the boundary was based on the first appearance datum (FAD) of the graptolite Monograptus uniformis angustidens (Nikiforova, Reference Nikiforova1977), rather than on the Devonian index graptolite Monograptus uniformis uniformis (Martinsson, Reference Martinsson1977). The first appearance datum of M. uniformis uniformis in the Tajna Beds is higher than the occurrence of encrinurids (Nikiforova, Reference Nikiforova1977). Moreover, chitinozoans in the Tajna Beds (later renamed the Tajna Formation) show that this unit is at least in part of Silurian age (Paris & Grahn, Reference Paris and Grahn1996). The claimed Early Devonian encrinurids from the Indian Point Formation in Québec are from a horizon above those containing Monograptus praehercynicus Jaeger, Monograptus ex gr. microdon Richter, Monograptus aequabilis aequabilis (Přibyl)) and Linograptus posthumus posthumus (Richter) (Bourque & Lesperance, Reference Bourque and Lesperance1977). This graptolite assemblage is presumed to belong to the Early Devonian M. uniformis zone (Lenz, Reference Lenz1972), but the index element M. uniformis uniformis has not been found in this assemblage.

Strusz (Reference Strusz1980) attributed an Early Devonian age to two species of encrinurids from Australia, but it was later proved that these records were the result of incorrect stratigraphic assignment (Campbell in Zhang & Sun, Reference Zhang and Sun2007). Owens et al. (Reference Owens, Ivanova, Kim, Popov and Feist2010) described the encrinurids from the basal 10 m of the upper member of the Zaamin Formation in the Zaamin River Basin, Uzbekistan. This member yielded the conodonts Ozarkodina steinchornensis remscheidensis and Amydrotaxis johnsoni, which are common in the Lochkovian (Klapper & Murphy, Reference Klapper and Murphy1980; Akhmedov, Reference Akhmedov2001; Wang et al. Reference Wang, Chen, Ziegler, Munchtseseg, Gereltsetseg and Undarya2005; Zherlygin, Reference Zherlygin2012), but may extend down into the Pridoli (Murphy et al. Reference Murphy, Valenzuela-Rios and Carls2004; Zherlygin, Reference Zherlygin2012). In addition, the exact horizon of the conodonts in the upper member of the Zaamin Formation is uncertain, so it is still unknown whether the encrinurids occur above or below these so-called Early Devonian conodonts. In China, Duan and An (Reference Duan and An2004) reported the encrinurid Encrinuropsis sinicus Kuo, 1962 from the upper part of the Erdaogou Formation in Jilin Province. This formation was originally regarded as Pridoli in age (Wang & Li, Reference Wang and Li1986) based on the conodont Spathognathodus steinhornensis eosteinhornensis, but Wang et al. (Reference Wang, Lang, Zhou, Yin and Li2014) considered that the conodont to have been misidentified and that there are no Silurian conodonts in the upper part of the Erdaogou Formation. Based on the conodont Neopanderodus sp. and other benthic fossils, Wang et al. (Reference Wang, Lang, Zhou, Yin and Li2014) inferred that a Lochkovian age for the upper part of the Erdaogou Formation cannot be excluded. However, the exact locations of encrinurids and conodonts are uncertain, so it is controversial whether encrinurids described by Duan and An (Reference Duan and An2004) appeared in the Early Devonian. The age of encrinurids from the lower part of the Wutubulake Formation in the Mangkelu section of western Junggar, Xinjiang was also considered to be the Early Devonian based on benthic animals such as other trilobites and corals (Zhang, Reference Zhang1983; Wang, Reference Wang1991), but later studies of graptolites from this formation changed its age to Pridoli (Cai et al. Reference Cai, Dou and Edwards1993; Ni et al. Reference Ni, Lenz and Chen1998).

Caudicriodus sp. (Fig. 4a–c) appears for the first time in bed 7-4 (72.1 m) of the Mangkelu II section in western Junggar, Xinjiang. The specimen differs from the Lochkovian Caudicriodus woschmidti or Caudicriodus hesperius in the absence of a posterior process. However, the specimen is intact (from lower view), and its small size and the presence of well-developed transverse ridges suggest that it may represent a juvenile specimen of the Early Devonian Caudicriodus (Drygant & Szaniawski, Reference Drygant and Szaniawski2012). According to Jeppsson (Reference Jeppsson1988), Caudicriodus (specifically Caudicriodus woschmidti) occurs slightly before Monograptus uniformis uniformis in some sections, but this fact may be due to facies control (Corradini & Corriga, Reference Corradini and Corriga2012). The appearance of Caudicriodus (or Icriodus) is still believed to coincide with the beginning of the Devonian period (Corradini & Corriga, Reference Corradini and Corriga2012; Slavik & Hladil, Reference Slavik and Hladil2020; Ferretti et al. Reference Ferretti, Corriga, Slavík and Corradini2022). Caudicriodus angustoides bidentatus (Fig. 4d–i) was found in bed 7-5 (74.5 m) of the Mangkelu II section. This subspecies is widely documented in the middle–upper Lochkovian (Savage, Reference Savage1976; Boncheva et al. Reference Boncheva, Sachanski, Lakova and Yaneva2007; Slavik et al. Reference Slavik, Carls, Hladil and Koptikova2012), but it may also extend downwards into the lower Lochkovian as demonstrated by its occurrence together with Caudicriodus woschmidti in Inner Mongolia, China (Wang, Reference Wang2006, Reference Wang2019). Thus, in the Mangkelu II section of western Junggar, Devonian strata begin at least in bed 7-4 (72.1 m), and the age of the encrinurid Batocara sp. in bed 7-5 (74.5 m) and bed 8-2 (77.9 m) is undoubtedly the Early Devonian, providing positive evidence that encrinurids cross the Silurian–Devonian boundary.

4.b. Implications for the Silurian–Devonian boundary

The Silurian–Devonian boundary is defined by the FAD of the graptolite Monograptus uniformis uniformis (Martinsson, Reference Martinsson1977), but conodonts are often used to determine the SDB in carbonate facies. At present, the FAD of Caudicriodus hesperius is widely used to define the boundary (Carls et al. Reference Carls, Slavík and Valenzuela-Rios2007; Corradini & Corriga, Reference Corradini and Corriga2012; Slavik et al. Reference Slavik, Carls, Hladil and Koptikova2012; Schönlaub et al. Reference Schönlaub, Corradini and Corriga2017; Hušková & Slavík, Reference Hušková and Slavík2019; Corradini et al. Reference Corradini, Corriga, Pondrelli and Suttner2020). However, both graptolites and conodonts are strongly controlled by lithofacies. They are rare or even absent in some areas lacking carbonate rocks and shales, or in shallow-water facies, so that the Silurian–Devonian boundary cannot be determined accurately in these areas. The FAD of the trilobite Warburgella rugulosa rugosa is also regarded as an important auxiliary indicator of the SDB, but the paleogeographic distribution of the Warburgella rugulosa group is relatively limited, with reliable records only from Europe, North Africa, North America and Central Asia (see Ormiston, Reference Ormiston1977; Maksimova, Reference Maksimova1980). A subspecies similar to W. rugulosa rugosa, i.e., Warburgella rugulosa sinensis, was reported from Qujing, Yunnan, China (Wu, Reference Wu1977), but was later revised as a separate species, Warburgella sinensis (Zhang & Sun, Reference Zhang and Sun2007). This means that the real Warburgella rugulosa group has not been found in China. Compared to the Warburgella rugulosa group, encrinurids are extensive in paleogeographic distribution and readily recognized in a variety of marine rocks and all strata containing encrinurids were dated as Silurian in age (Chlupáč et al. Reference Chlupáč, Jaeger and Zikmundova1972; Holloway & Neil, Reference Holloway and Neil1982; Liao et al. Reference Liao, Rong, Hu, Peng and Li1995; Duan & An, Reference Duan and An2004; Zhang & Sun, Reference Zhang and Sun2007). The highest horizon of encrinurids in the Mangkelu II section located above the FAD of Caudicriodus, indicating, however, that these trilobites can continued up to the Early Devonian and are not exclusively Silurian. Therefore, the SDB previously determined on the basis of encrinurids in some sections need to be redefined by graptolites or conodonts (e.g., Guo, Reference Guo1962; Liao et al. Reference Liao, Rong, Hu, Peng and Li1995), and the SDB of these sections are likely to need to be moved downwards.

The highest horizon of encrinurids in the Mangkelu II section is bed 8-2 (77.9 m), and the overlying bed 8-3 (82.5 m) yields abundant and diverse trilobites but no encrinurids. The conodonts Caudicriodus angustoides bidentatus (Fig. 4j–l) and Zieglerodina planilingua (Fig. 4m–r) were also found in bed 8-3 (82.5 m). Caudicriodus angustoides bidentatus is restricted to the Lochkovian (Savage, Reference Savage1976; Wang, Reference Wang2006; Boncheva et al. Reference Boncheva, Sachanski, Lakova and Yaneva2007; Slavik et al. Reference Slavik, Carls, Hladil and Koptikova2012; Wang, Reference Wang2019), and Z. planilingua is commonly documented from the Pridoli to the lower Lochkovian (Murphy et al. Reference Murphy, Valenzuela-Rios and Carls2004; Corradini & Corriga, Reference Corradini and Corriga2012; Corriga et al. Reference Corriga, Corradini and Walliser2014a; Corradini et al. Reference Corradini, Corriga, Pondrelli and Suttner2020). In addition, scyphocrinoid plate-type loboliths were found in bed 8-3 and bed 11 of this section (Zong & Gong, Reference Zong and Gong2020). The appear and disappear abruptly within a relatively short stratigraphic interval, occurring only in strata near the SDB (Haude, Reference Haude1992). Plate-type lobolith-bearing strata in Baoshan, Yunnan Province, China, also yielded Monograptus cf. uniformis angustidens, M. microden and Caudicriodus woschmidti, are restricted to the Lochkovian (Shi & Gong, Reference Shi and Gong1992). In the Tafilalt region of southeastern Morocco, according to conodont biostratigraphy, Camarocrinus, Marhoumacrinus and their plate-type loboliths are present at the top of the Pridoli and extend into the Caudicriodus hesperius zone at the base of the Lochkovian (Corriga et al. Reference Corriga, Corradini, Haude and Walliser2014b; Haude et al. Reference Haude, Corriga, Corradini and Walliser2014).

In view of above, the stratigraphic extension of plate-type loboliths in the Mangkelu II section in western Junggar should remain in the Devonian (Lochkovian) first conodont zone, which limits the highest horizon of encrinurids to the Caudicriodus hesperius zone, and most likely to the lower part of that zone, not far above the Silurian–Devonian boundary. Thus, in areas where plankton is absent, or where shale and carbonate rocks are not developed, the topmost horizon of encrinurids may be used as an approximate indicator of the SDB. In the absence of standard graptolites or conodonts, encrinurid-bearing strata can still be roughly assigned to the Silurian.

5. Conclusions

The Lochkovian conodonts Caudicriodus sp. and Caudicriodus angustoides bidentatus were found below the highest horizon of encrinurids in western Junggar, Xinjiang, NW China, providing evidence that encrinurid trilobites persisted into the earliest Devonian, and did not become extinct at the end of Silurian. The upper stratigraphic limit of encrinurids here is in the Caudicriodus hesperius Zone of the lower Lochkovian, as indicated by conodonts and plate-type loboliths occurring higher in the sequence.

Encrinurids are widely distributed, including in carbonate, clastic and pyroclastic facies, and are easily identified. The encrinurids Batocara sp. survived into the earliest Lochkovian in at least NW China. These factors mean that the highest horizon of encrinurids which have been confirmed in other areas to associate with graptolites and conodonts near the SDB can be used to define the Silurian–Devonian boundary approximately in those areas or sections that lack index fossils such as graptolites and conodonts.

Acknowledgements

We are grateful for the constructive comments from Greg Edgecombe and David Holloway, which improved the clarity and scope of the manuscript. This study was supported by the National Natural Science Foundation of China (Grant Nos. 42072041, 41702006). We are grateful to Zhihong Wang (Wuhan Geological Survey Center of China Geological Survey), Xinsong Zhang and Weidong Du (Fuzhou University), and Haohong Xie (China University of Geosciences, Wuhan) for their help in the field work.

Competing interests

No conflict of interest exits in the submission of this manuscript, and the manuscript is approved by all authors for publication.

Footnotes

These authors contributed equally to this work.

References

Akhmedov, NA (ed) (2001) Stratigraficheskiy slovar Uzbekistana. Tashkent: Gidroingeo, 580 p.Google Scholar
Bault, V, Balseiro, D, Monnet, C and Crônier, C (2022) Post-Ordovician trilobite diversity and evolutionary faunas. Earth-Science Reviews 230, 104035.CrossRefGoogle Scholar
Barrick, JE, Sundgren, JR and Mcadams, NEB (2021) Endemic earliest Lochkovian species of Caudicriodus (Conodont) from southern Laurentia and the Silurian–Devonian boundary. Papers in Palaeontology 7, 1585–600.CrossRefGoogle Scholar
Biske, JS, Gorianov, VB and Rzonsnickaja, MA (1977) Tien-shan. In The Silurian–Devonian boundary, Martinsson, A., Ed. IUGS Series A 5, 227–37.Google Scholar
Boncheva, L, Sachanski, V, Lakova, I and Yaneva, M (2007) Facies transition and biostratigraphic correlation of the Upper Silurian and Lower Devonian in West Bulgaria. Geological Quarterly 51, 407–18.Google Scholar
Boucot, AJ (1985) Late Silurian–Early Devonian biogeography, provincialism, evolution and extinction. Philosophical Transactions of the Royal Society B. Biological Sciences 309, 323–39.Google Scholar
Bourque, PA and Lesperance, PJ (1977) Gaspé Peninsula, Québec. In The Silurian–Devonian boundary, Martinsson, A., Ed. IUGS Series A 5, 245–55.Google Scholar
Cai, CY, Dou, YW and Edwards, D (1993) New observations on a Pridoli plant assemblage from north Xinjiang, northwest China, with comments on its evolutionary and palaeogeographical signifificance. Geological Magazine 130, 155–70.Google Scholar
Cai, TC (1999) Lithostratigraphy of Xinjiang Uygur Autonomous Region. Wuhan, China: University of Geosciences Press, 430 p.Google Scholar
Carls, P, Slavík, L and Valenzuela-Rios, JI (2007) Revisions of conodont biostratigraphy across the Silurian–Devonian boundary. Bulletin of Geosciences 82, 145–64.CrossRefGoogle Scholar
Chen, JF, Han, BF, Ji, JQ, Zhang, L, Xu, Z, He, GQ and Wang, T (2010) Zircon U–Pb ages and tectonic implications of Paleozoic plutons in northern West Junggar, North Xinjiang, China. Lithos 115, 137–52.CrossRefGoogle Scholar
Chlupáč, I (1994) Devonian trilobites––evolution and events. Geobios 27, 487505.CrossRefGoogle Scholar
Chlupáč, I, Jaeger, H and Zikmundova, J (1972) The Silurian–Devonian boundary in the Barrandian. Bulletin of Canadian Petroleum Geology 20, 104–74.Google Scholar
Corradini, C and Corriga, MG (2012) A Pridoli–Lochkovian conodont zonation in Sardinia and the Carnic Alps: implications for a global zonation scheme. Bulletin of Geosciences 87, 635–50.CrossRefGoogle Scholar
Corradini, C, Corriga, MG, Pondrelli, M and Suttner, TJ (2020) Conodonts across the Silurian/Devonian boundary in the Carnic Alps (Austria and Italy). Palaeogeography, Palaeoclimatology, Palaeoecology 549, 109097.CrossRefGoogle Scholar
Corriga, MG, Corradini, C, Haude, R and Walliser, OH (2014b) Conodont and crinoid stratigraphy of the upper Silurian and Lower Devonian scyphocrinoid beds of Tafilalt, southeastern Morocco. GFF 136, 65–9.CrossRefGoogle Scholar
Corriga, MG, Corradini, C and Walliser, OH (2014a) Upper Silurian and Lower Devonian conodonts from Tafilalt, southeastern Morocco. Bulletin of Geoscience 89, 183200.Google Scholar
Drygant, D and Szaniawski, H (2012) Lochkovian conodonts from Podolia, Ukraine, and their stratigraphic significance. Acta Palaeontologica Polonica 57, 833–61.Google Scholar
Duan, JY and An, SL (2004) Silurian trilobites from central Jilin Province, China. Journal of Jilin University (Earth Science Edition) 34, 111.Google Scholar
Ferretti, A, Corriga, MG, Slavík, L and Corradini, C (2022) Running across the Silurian/Devonian Boundary along Northern Gondwana: a conodont perspective. Geosciences 12, 43.CrossRefGoogle Scholar
Fletcher, HO (1975) Silurian and Lower Devonian fossils from the Cobar Area of New South Wales. Records of the Australian Museum 30, 6585.CrossRefGoogle Scholar
Guo, HJ (1962) Some Silurian trilobites from the Ertaogou Group of Jilin. Acta Palaeontologica Sinica 10, 369–81.Google Scholar
Gong, YM and Zong, RW (2015) Paleozoic stratigraphic regionalization and palaeogeographical evolution in Western Junggar, northwestern China. Earth Science––Journal of China University of Geosciences 40, 461–84.Google Scholar
Haude, R (1992) Scyphocrinoiden, die Bojen–Seelilien im hohen Silur–tiefen Devon. Palaeontographica Abteilung A 222, 141–87.Google Scholar
Haude, R, Corriga, MG, Corradini, C and Walliser, OH (2014) Buoy crinoids (Scyphocrinitidae, Echinodermata) in newly dated upper Silurian to lowermost Devonian strata of SE Morocco. Göttingen Contributions to Geosciences 77, 129–45.Google Scholar
Holloway, DJ and Neil, JV (1982) Trilobites from the Mount Ida Formation (Late Silurian–Early Devonian), Victoria. Proceedings of the Royal Society of Victoria 94, 133–54.Google Scholar
Hou, HF, Xiang, LW, Lai, CG and Lin, BY (1979) New advances in the study of the Paleozoic strata in Tianshan–Xing’an region. Journal of Stratigraphy 3, 2133.Google Scholar
Hušková, A and Slavík, L (2019) In search of Silurian/Devonian boundary conodont markers in carbonate environments of the Prague Synform (Czech Republic). Palaeogeography, Palaeoclimatology, Palaeoecology 549, 109126.CrossRefGoogle Scholar
Jeppsson, L (1988) Conodont biostratigraphy of the Silurian–Devonian boundary stratotype at Klonk, Czechoslovakia. Geologica et Palaeontologica 22, 2131.Google Scholar
Klapper, G and Murphy, MA (1980) Conodont zonal species from the delta and pesavis Zones (Lower Devonian) in central Nevada. Neues Jahrbuch für Geologie und Palaöntologie, Monatshefte 8, 490504.CrossRefGoogle Scholar
Lenz, AC (1972) Graptolites from the Laforce and St. Léon formations, northern Gaspé, Québec. Canadian Journal of Earth Sciences 9, 1148–62.CrossRefGoogle Scholar
Liao, WH, Rong, JY, Hu, ZX, Peng, YJ and Li, CT (1995) Silurian–Devonian biostratigraphy, synecology and palaeobiogeography from central Jilin, NE China. Journal of Stratigraphy 19, 241–9.Google Scholar
Maksimova, ZA (1975) Trilobity in Kharakteristika fauny pogranichnykh sloev Silurian–Devonian tsentral ’nogo Kazakhstana. Materialy po geologii tsentral ’nogo Kazakhstana 12, 119–33.Google Scholar
Maksimova, ZA (1980) Biostratigraphic zones based on trilobites in USSR Devonian deposits. International Geology Review 22, 477–89.CrossRefGoogle Scholar
Maksimova, ZA, Modzhalevskaya, YeA, Kaplun, LI and Senkevich, MA (1973) The Lower Devonian of the Pacific paleobiogeographical region of USSR. International Geology Review 15, 626–40.CrossRefGoogle Scholar
Martinsson, A (1977) The Silurian-Devonian boundary: final report of the Committee on the Silurian-Devonian Boundary within IUGS Commission on Stratigraphy and a state of the art report for Project Ecostratigraphy. IUGS Series 5, 134.Google Scholar
Murphy, MA, Valenzuela-Rios, JI and Carls, P (2004) On Classification of Pridoli (Silurian)–Lochkovian (Devonian) Spathognathodontidae (Conodonts). University of California, Riverside, Campus Museum Contributions 6, 125.Google Scholar
Ni, YN, Lenz, AC and Chen, X (1998) Pridoli graptolites from northern Xinjiang, Northwest China. Canadian Journal of Earth Sciences 35, 1123–33.CrossRefGoogle Scholar
Nikiforova, OI (1977) Podolia. In The Silurian–Devonian boundary. IUGS Series A 5, 5264.Google Scholar
Ormiston, AR (1977) Trilobites. In The Silurian–Devonian boundary. IUGS Series A 5, 320–6.Google Scholar
Owens, RM, Ivanova, O, Kim, I, Popov, LE and Feist, R (2010) Lower and Middle Devonian trilobites from southern Uzbekistan. Memoirs of the Association of Australasian Palaeontologists 39, 211–44.Google Scholar
Paris, F and Grahn, Y (1996) Chitinozoa of the Silurian–Devonian boundary sections in Podolia, Ukraine. Palaeontology 39, 629–49.Google Scholar
Pärnaste, H (2006) The earliest encrinurid trilobites from the east Baltic and their taxonomic interest. Palaeontology 49, 155–70.CrossRefGoogle Scholar
Savage, NM (1976) Lower Devonian (Gedinnian) conodonts from the Grouse Creek area, Klamath Mountains, northern California. Journal of Paleontology 50, 1180–90.Google Scholar
Schönlaub, HP, Corradini, C and Corriga, MG (2017) Chrono-, litho-and conodont bio-stratigraphy of the Rauchkofel Boden Section (Upper Ordovician–Lower Devonian), Carnic Alps, Austria. Newsletters on Stratigraphy 50, 445–69.CrossRefGoogle Scholar
Scotese, CR (2021) An atlas of Phanerozoic Paleogeographic maps: the seas come in and the seas go out. Annual Review of Earth and Planetary Sciences 49, 679728.CrossRefGoogle Scholar
Shi, Y and Gong, DM (1992) Advances of Devonian research in Baoshan–Shidian area, W–Yunan. Journal of Chengdu College of Geology 19, 2132.Google Scholar
Slavik, L, Carls, R, Hladil, J and Koptikova, L (2012) Subdivision of the Lochkovian stage based on conodont faunas from the stratotype area (Prague Synform, Czech Republic). Geological Journal 47, 616–31.CrossRefGoogle Scholar
Slavik, L and Hladil, J (2020) Early Devonian (Lochkovian– early Emsian) bioevents and conodont response in the Prague Synform (Czech Republic). Palaeogeography, Palaeoclimatology, Palaeoecology 549, 109148.CrossRefGoogle Scholar
Strusz, DL (1980) The Encrinuridae and related trilobite families, with a description of Silurian species from southeastern Australia. Palaeontographica Abteilung A 168, 168.Google Scholar
Temple, JT and Tripp, RP (1979) An investigation of the Encrinurinae (Trilobita) by numerical taxonomic methods. Transactions of the Royal Society of Edinburgh 70, 223–50.CrossRefGoogle Scholar
Temple, JT and Wu, HJ (1990) Numerical taxonomy of Encrinurinae (Trilobita): additional species from China and elsewhere. Transactions of the Royal Society of Edinburgh: Earth Sciences 81, 209–19.CrossRefGoogle Scholar
Wang, BY (1991) Stratigraphic sequences and boundary discussion of Lower and Middle Devonian in northern Xinjiang. Xinjiang Geology 9, 249–59.Google Scholar
Wang, CY (2019) Devonian conodonts in China. Hangzhou: Zhejiang University Press, 719 p.Google Scholar
Wang, CY, Chen, MJ, Ziegler, W, Munchtseseg, J, Gereltsetseg, J and Undarya, J (2005) The first discovery of the middle Lochkovian (Devonian) conodonts in South Gobi, Mongolia. Science in China Series D: Earth Sciences 48, 4852.CrossRefGoogle Scholar
Wang, CY, Lang, JB, Zhou, XD, Yin, CJ and Li, DJ (2014) Progress and problems in the study of conodont biostratigraphy in Jilin province. Journal of Stratigraphy 38, 299304.Google Scholar
Wang, CY and Li, DJ (1986) Conodonts from the Erdaogou Formation in central Jilin province. Acta Micropalaeontologica Sinica 3, 421–8.Google Scholar
Wang, P (2006) Lower Devonian conodonts of the Bateaobao area in Darhan Mumingan joint Banner, Inner Mongolia. Acta Micropalaeontologica Sinica 23, 199234.CrossRefGoogle Scholar
Windley, BF, Alexeiev, D, Xiao, WJ, Kröner, A and Badarch, G (2007) Tectonic models for accretion of the Central Asian Orogenic Belt. Journal of Geological Society, London 164, 3147.CrossRefGoogle Scholar
Wu, HJ (1977) Comments on new genera and species of Silurian-Devonian trilobites in southwest China and their significance. Acta Palaeontologica Sinica 16, 95117.Google Scholar
Xiao, SL, Hou, HF, Wu, SZ, Liu, BP, Wang, BY, Wang, SR, Cai, TC, Gong, YM, Yan, Y and Cui, X (1992) The Researches of Devonian System in North Xinjiang. Urumqi: Xinjiang Science Technology & Hygiene Publishing House, 257 p.Google Scholar
Xiao, SL, Wu, SZ, Wang, BY, Wang, SR and Hou, HF (1991) Some new advances in study on Devonian in Sarburti region of west Junggar, Xinjiang. In Geoscience of Xinjiang (No. 3) (ed The Editorial Committee of Geoscience of Xinjiang of Project 305), pp. 19. Beijing: Geological Publishing House.Google Scholar
Xiao, WJ, Han, CM, Yuan, C, Sun, M, Lin, SF, Chen, HL, Li, ZL, Li, JL and Sun, S (2008) Middle Cambrian to Permian subduction-related accretionary orogenesis of northern Xinjiang, NW China: Implications for the tectonic evolution of central Asia. Journal of Asian Earth Sciences 32, 102–17.CrossRefGoogle Scholar
Zeng, YC and Xiao, SL (1991) Devonian system. In The Palaeozoic Erathem of Xinjiang (No. 2 Stratigraphic Summary of Xinjiang) (ed Institute of Geology and Mineral Resources, No. 1 Regional Geological Surveying Party, Bureau of Geology and Mineral Resources of Xinjiang), pp. 16–8. Urumqi: Xinjiang People’s Publishing House.Google Scholar
Zhang, T.R., 1983. Trilobita. In Palaeontological Atlas of Northwest China, Volume of Xinjiang Uygur Autonomous Region II (Late Paleozoic) (ed In Regional Geological Survey and Institute of Geosciences, Geological Bureau of Xinjiang, Geological Survey of Xinjiang Petroleum Bureau), pp. 534–55. Beijing: Geological Publishing House.Google Scholar
Zhang, WT and Sun, XW (2007) Silurian trilobites from Santanghu, Barkol, NE Xinjiang. Acta Palaeontologica Sinica 46, 3344.Google Scholar
Zherlygin, AL (2012) Devonian organic massif in the basins of the rivers Kara-Silovayaha (the southest Pai-Hoi). Journal of Mining Institute 195, 3740.Google Scholar
Zong, RW and Gong, YM (2020) Discovery of scyphocrinoid loboliths in western Junggar, Xinjiang, NW China: implications for scyphocrinoid paleobiogeography and identification of the Silurian–Devonian boundary. Palaeogeography, Palaeoclimatology, Palaeoecology 557, 109914.CrossRefGoogle Scholar
Figure 0

Figure 1. Geological background and location map of the study area. (a), Paleogeographical location of western Junggar in the Silurian–Devonian transition (modified from Scotese, 2021). (b), (c), Location of the Mangkelu II section and the geological map of study area (modified from Zong & Gong, 2020). (d), Stratigraphic column of Mangkelu II section. Abbreviations: WJ, western Junggar, Kz., Kazakhstan, PAO, Paleo-Asian Ocean, Au., Australia.

Figure 1

Figure 2. Lithological features and fossils near the Silurian–Devonian boundary of Mangkelu II section in western Junggar, Xinjiang. (a), The stratigraphic division of the Mangkelu II section and the levels of trilobites (red arrows) and important conodonts (blue arrows). (b), (c), The boundary between the Wutubulake Formation and the overlying Mangeer Formation is located between bed 7 and bed 8, Fig. c shows the local amplification of Fig. b. (d), Calcareous siltstone lens in tuffaceous medium sandstone in bed 7-4 of the Wutubulake Formation. (e), Tuffaceous siltstone in bed 7-2 of the Wutubulake Formation. (f), Tuffaceous pebbly coarse sandstone containing crinoid stems in bed 6-3 of the Wutubulake Formation. (g), Tuffaceous medium-coarse sandstone containing encrinurids pygidium at the bottom of bed 7-1 of the Wutubulake Formation. (h), Bioclastic limestone interlayer in bed 7-5 of the Wutubulake Formation. (i), (j), Plate-type lobolith of scyphocrinoid in bed 8-3 of the Mangeer Formation.

Figure 2

Figure 3. Encrinurid trilobiteBatocarasp. from the Wutubulake and Mangeer formations (near the Silurian-Devonian boundary) of Mangkelu II section, western Junggar, Xinjiang. (a)–(c), pygidium, BGEG-MII/T007, bed 7-5 (74.5 m), dorsal view (a), left lateral view (b), and posterior view (c). (d), Incomplete cranidium, BGEG-MII/T010, bed 7-4 (69.5 m), dorsal view. (e)–(f), Complete pygidia, BGEG-MII/T004, BGEG-MII/T015, bed 7-4 (62 m), bed 8-2 (77.9 m), dorsal view. (g)–(j), Incomplete pygidia, BGEG-MII/T012, BGEG-MII/T006, BGEG-MII/T013, BGEG-MII/T011, bed 7-4 (62 m), bed 7-4 (62 m), bed 8-2 (77.9 m), bed 7-4 (69.5 m), dorsal view, and (h) is an internal mold.

Figure 3

Figure 4. The earliest Devonian conodonts from Mangkelu II section in western Junggar, NW Xinjiang. (a)–(c), Caudicriodus sp., BGEG-MII/C/72.1/001, upper, lateral, and lower views of the I element, Bed 7-4 (72.1 m). (d)–(i), Caudicriodus angustoides bidentatus, BGEG-MII/C/74.5/018, BGEG-MII/C/74.5/019, upper, lateral, and lower views of the I element, Bed 7-5 (74.5 m). (j)–(l), Caudicriodus angustoides bidentatus, BGEG-MII/C/82.5/006, upper, lateral, and lower views of the I element, Bed 8-3 (82.5 m). (m)–(r), Zieglerodina planilingua, BGEG-MII/C/82.5/007, BGEG-MII/C/82.5/008, upper, lateral, and lower views of the P elements, Bed 8-3 (82.5 m).