Paleo-trade wind directions over the Yangtze Carbonate Platform during the Cambrian–Ordovician, Southern China

Chenlin Hu; Tianyou Qin; Jinghui Ma; Changcheng Han; Xuliang Wang

doi:10.1017/S0016756823000286

Paleo-trade wind directions over the Yangtze Carbonate Platform during the Cambrian–Ordovician, Southern China

Published online by Cambridge University Press: 17 May 2023

Chenlin Hu

Tianyou Qin ,

Jinghui Ma ,

Changcheng Han and

Xuliang Wang

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Chenlin Hu: Affiliation:
Xinjiang Key Laboratory for Geodynamic Processes and Metallogenic Prognosis of the Central Asian Orogenic Belt, Xinjiang University, Urumqi 830017, China School of Geology and Mining Engineering, Xinjiang University, Urumqi 830017, China
Tianyou Qin: Affiliation:
Xinjiang Key Laboratory for Geodynamic Processes and Metallogenic Prognosis of the Central Asian Orogenic Belt, Xinjiang University, Urumqi 830017, China School of Geology and Mining Engineering, Xinjiang University, Urumqi 830017, China
Jinghui Ma*: Affiliation:
Xinjiang Key Laboratory for Geodynamic Processes and Metallogenic Prognosis of the Central Asian Orogenic Belt, Xinjiang University, Urumqi 830017, China School of Geology and Mining Engineering, Xinjiang University, Urumqi 830017, China
Changcheng Han*: Affiliation:
Xinjiang Key Laboratory for Geodynamic Processes and Metallogenic Prognosis of the Central Asian Orogenic Belt, Xinjiang University, Urumqi 830017, China School of Geology and Mining Engineering, Xinjiang University, Urumqi 830017, China
Xuliang Wang: Affiliation:
Xinjiang Key Laboratory for Geodynamic Processes and Metallogenic Prognosis of the Central Asian Orogenic Belt, Xinjiang University, Urumqi 830017, China School of Geology and Mining Engineering, Xinjiang University, Urumqi 830017, China
*: Author for correspondence: Jinghui Ma, Email: majinghui10@xju.edu.cn; Changcheng Han, Email: hanchangcheng@xju.edu.cn
Author for correspondence: Jinghui Ma, Email: majinghui10@xju.edu.cn; Changcheng Han, Email: hanchangcheng@xju.edu.cn

Article contents

Abstract
Introduction
Geological setting
Sampling and methods
Results
Discussion
Conclusions
Supplementary material
Data availability
Conflicts of interest
References

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Abstract

The Sichuan Basin was a part of the Yangtze Carbonate Platform (YCP) during the Cambrian–Ordovician, and marine carbonates were deposited in the basin during this interval. Although previous studies have evaluated the paleogeography, paleoclimate and paleoecology of this basin, they have primarily focused on the paleoecology and biological evolution in the basin; however, analysis of paleogeography and paleoclimate is lacking. This study integrated outcrop sedimentological and magnetic fabric data to document sedimentary differentiation and anisotropy of magnetic susceptibility (AMS) within the YCP. The aims of this study were to infer paleowind directions during each epoch of the Cambrian–Ordovician and to constrain the paleogeographic location of the YCP. The northwestern, central and southeastern sides of the YCP were characterized by high-energy deposition (e.g. sub-angular to rounded intraclasts), medium-energy deposition (e.g. sub-angular to sub-rounded intraclasts) and low-energy deposition (e.g. angular to sub-angular intraclasts), respectively. The centroid D-Kmax values for the Early, Middle and Late Cambrian were 116° ± 52°, 145° ± 57° and 159° ± 62° from the present north, respectively; corresponding values for the Early, Middle and Late Ordovician were 169° ± 70°, 139° ± 73° and 91° ± 68° from the present north, respectively. Sedimentary differentiation and AMS results indicated that the prevailing wind directions during the Early Cambrian, Middle Cambrian, Late Cambrian, Early Ordovician, Middle Ordovician and Late Ordovician were 296° ± 52°, 325° ± 57°, 339° ± 62°, 349° ± 70°, 319° ± 73° and 271° ± 68° from the present north, respectively. The present study provides evidence for the location of the YCP during the Cambrian–Ordovician via the correspondence between the paleowind directions over the YCP and the trade winds in the Northern and Southern hemispheres. The novelty of this study lies in the following aspects: (1) it integrates microfacies and AMS analyses to establish paleowind patterns; (2) it constrains the paleo-hemispheric location of the YCP during the Cambrian–Ordovician; and (3) it provides a reference for further studies of the paleoclimate and paleogeography of the YCP during the Cambrian–Ordovician.

Keywords

Sichuan Basin Paleozoic paleoclimate paleogeography trade winds carbonate microfacies

Type: Original Article
Information: Geological Magazine , Volume 160 , Issue 6 , June 2023 , pp. 1160 - 1176

DOI: https://doi.org/10.1017/S0016756823000286 [Opens in a new window]
Copyright: © The Author(s), 2023. Published by Cambridge University Press

1. Introduction

Carbonate platform sediments undergo sedimentary differentiation under the action of long-term prevailing winds (Han et al. Reference Han, Tian, Hu, Liu, Wang, Huan and Feng2020; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b; Hu et al. Reference Hu, Han, Ma, Deng and Zhao2022). Anisotropy of magnetic susceptibility (AMS) has been widely used as an indicator of paleowind or paleocurrent directions (Lagroix & Banerjee, Reference Lagroix and Banerjee2002; Nawrocki et al. Reference Nawrocki, Gozhik, Lanczont, Panczyk, Komar, Bogucki, Williams and Czupyt2018; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b). Hydrodynamic experiments have demonstrated the influence of wind or water motion on grain orientation (Rees & Woodall, Reference Rees and Woodall1975; Tarling & Hrouda, Reference Tarling and Hrouda1993; Hu et al. Reference Hu, Zhang, Feng, Wang, Jiang and Jiao2017; Zhang-YF et al. Reference Zhang, Hu, Wang, Wang, Jiang and Li2017; Zhang-YF et al. Reference Zhang, Hu, Wang, Ma, Wang and Jiang2018). Under calm conditions, the maximum AMS axes are randomly distributed. Under a strong unidirectional flow, oblate particles tend to produce an imbricate fabric in the direction of the flow and elongated particles are aligned parallel to the direction of transport. Under bidirectional flow, elongated grains may align perpendicular to the directions of fluid movement (Rees & Woodall, Reference Rees and Woodall1975; Tarling & Hrouda, Reference Tarling and Hrouda1993; Hu et al. Reference Hu, Zhang, Feng, Wang, Jiang and Jiao2017). This study reconstructed paleowind directions during each epoch of the Cambrian–Ordovician the Yangtze Carbonate Platform (YCP) using sedimentary differentiation and AMS analysis.

The YCP was located in the low-latitude trade winds belt during the Cambrian–Ordovician, and marine carbonates were deposited there (Li et al. Reference Li, Li, Wang and Kiessling2015; Zhang et al. Reference Zhang, Song, Jiang, Jiang, Jia, Huang, Wen, Liu, Xie, Liu, Wang, Shan and Wu2019; Cheng et al. Reference Cheng, Li, Zhang, Liu, Peng, Hou, Wen, Xia, Wang, Liu, Zhong, Huang, Liu, Yuan and Yao2020). Like other platforms, the YCP was subjected to extensive global transgression during the Cambrian (Dalziel, Reference Dalziel2014; Chang et al. Reference Chang, Chu, Feng, Huang and Chen2018; Zhai et al. Reference Zhai, Wu, Ye, Zhang and Wang2018; Wu et al. Reference Wu, Tian, Li, Li and Ji2021). The water in the ocean was warm and conducive to the growth and development of marine organisms (Peters & Gaines, Reference Peters and Gaines2012; Karlstrom et al. Reference Karlstrom, Hagadorn, Gehrels, Matthews, Schmitz, Madronich, Mulder, Pecha, Giesler and Crossey2018; Wood et al. Reference Wood, Liu, Bowyer, Wilby, Dunn, Kenchington, Hoyal Cuthill, Mitchell and Penny2019). Numerous organisms began to emerge during this time, and some primitive invertebrates gradually evolved into invertebrates with hard shells; this phenomenon is known as the ‘Cambrian Explosion’ (Jin et al. Reference Jin, Li, Algeo, Planavsky, Cui, Yang, Zhao, Zhang and Xie2016; Aria & Caron, Reference Aria and Caron2019; Hoyal Cuthill et al. Reference Hoyal Cuthill, Guttenberg and Budd2020). As part of the most extensive transgression in the Early Paleozoic, conditions during the Ordovician favoured the further development of invertebrates (Kröger, Reference Kröger2018; Stigall et al. Reference Stigall, Edwards, Freeman and Rasmussen2019; Fang et al. Reference Fang, Li, Zhang, Song and Zhang2020; Harper et al. Reference Harper, Cascales-Miñana, Kroeck and Servais2021). The paleoecology and biological evolution of the YCP during the Cambrian–Ordovician have been extensively investigated (e.g. Li et al. Reference Li, Li, Wang and Kiessling2015; Lee & Riding, Reference Lee and Riding2018; Zheng et al. Reference Zheng, Clausen, Feng and Servais2020), but studies on its paleogeography and paleoclimate are scarce (e.g. Torsvik & Cocks, Reference Torsvik, Cocks, Harper and Servais2013; Zhang et al. Reference Zhang, Li, Li, Kiessling and Wang2016; Cocks & Torsvik, Reference Cocks and Torsvik2021). The paleogeography and paleoclimate influence paleoecology and biological evolution in a region, and therefore, it is necessary to comprehensively understand these aspects.

Most scholars hold that the YCP was located in low-latitude area of the Northern and Southern hemispheres during the Cambrian–Ordovician. Some scholars hold that the YCP drifted from the Southern Hemisphere (∼12°S) to the Northern Hemisphere (∼11°N), then back to the Southern Hemisphere (∼49°S), and finally drifted to the Northern Hemisphere (∼7°N) from the Middle Cambrian to the Middle Ordovician (e.g. Huang et al. Reference Huang, Zhu, Otofuji and Yang2000). Other scholars believe that the platform first drifted southward across the equator from the Northern Hemisphere (∼13°N) to the Southern Hemisphere (∼28°S) and then drifted northward to a location near the equator from the Early Cambrian to the Late Ordovician (e.g. Torsvik & Cocks, Reference Torsvik, Cocks, Harper and Servais2013; Cocks & Torsvik, Reference Cocks and Torsvik2021). The paleogeographic constraints (paleomagnetic or otherwise) are testable based on the expected paleoclimate conditions, especially the paleowind directions. The paleo-coordinate framework during the Cambrian–Ordovician in the trade wind belt indicates that the prevailing winds in the Northern and Southern hemispheres at the time were from northeast and from southeast, respectively (Kajtar et al. Reference Kajtar, Santoso, McGregor, England and Baillie2018; Helfer et al. Reference Helfer, Nuijens, De Roode and Siebesma2020, Reference Helfer, Nuijens and Dixit2021). On the whole, there is no consensus regarding the specific paleogeographic site and orientation of the YCP (Huang et al. Reference Huang, Zhu, Otofuji and Yang2000; Popov et al. Reference Popov, Bassett, Zhemchuzhnikov, Holmer and Klishevich2009; Nardin et al. Reference Nardin, Goddéris, Donnadieu, Hir, Blakey, Pucéat and Aretz2011; Torsvik & Cocks, Reference Torsvik, Cocks, Harper and Servais2013; Cocks & Torsvik, Reference Cocks and Torsvik2021; Harper et al. Reference Harper, Cascales-Miñana, Kroeck and Servais2021). These conflicting proposals emphasize the need to reconstruct paleowind directions.

The present study conducted an integrated analysis of bed- to platform-scale variations in sediments based on outcrop data to quantitatively reconstruct paleowind directions. One novel feature of the present study is the inclusion of quantitative measurements of sediment properties potentially influenced by the wind and wind-generated currents, such as bedding thickness and grain size and sorting, across the YCP. The aims of the present study were to (1) quantitatively reconstruct paleowind directions over the YCP during the Cambrian–Ordovician and (2) constrain the paleogeographic location of the YCP. The results of the present study can serve as a reference for the integrated use of sedimentological and AMS data for the recognition of paleowind directions over ancient carbonate platforms.

2. Geological setting

The Sichuan Basin is a gas-bearing superimposed basin (with complex structure due to vertical stacking of different structural layers) that occupies an area of ∼1.9 × 10⁵ km². It is mainly distributed in Sichuan Province and Chongqing City, the southern part of Shaanxi, eastern portion of Guizhou and western part of Hubei. The basin is bounded by the Micang and Daba mountains in the north, the Daliang and Loushan mountains in the south, the Longmen Mountains in the west and Qiyao Mountain in the east (Liu et al. Reference Liu, Yang, Deng, Zhong, Wen, Sun, Li, Jansa, Li, Song, Zhang and Peng2021; Cheng et al. Reference Cheng, Ding, Pan, Zou, Li, Yin and Ding2022; Dong et al. Reference Dong, Han, Santosh, Qiu, Liu, Ma, He and Hu2022). The Sichuan Basin is situated on a basement of pre-Sinian metamorphic and igneous rocks and contains marine and continental strata with the thickness of 6–12 km (Shi et al. Reference Shi, Cao, Selby, Tan, Luo and Hu2020; Zhao et al. Reference Zhao, Hu, Wang, Li, Tan, She, Zhang, Qiao and Wang2020; Miao et al. Reference Miao, Pei, Su, Sheng, Feng, Jiang, Liang and Hong2022). This study primarily focused on marine carbonate deposits in the YCP region, where the Sichuan Basin was located during the Cambrian–Ordovician (Figs. 1, 2).

Fig. 1. Regional index map showing the study area. (a) Simplified map of China showing the location of the YCP (after Chen et al. Reference Chen, Rong, Li and Boucot2004). (b) Paleogeographic map of the YCP during the Late Ordovician, showing the outcrop locations used in the present study (after Chen et al. Reference Chen, Rong, Li and Boucot2004). Detailed information of the nine outcrops (LJ, FD, YK, YS, NY, YJ, HH, JF, NS and YH) is provided in Table S1.

Fig. 2. Cambrian–Ordovician stratigraphy in the Sichuan Basin area of the YCP (after Yang et al. Reference Yang, Xie, Wei, Liu, Zeng, Xie and Jin2012).

2.a. Tectonic setting

The Sichuan Basin was in an extensional tectonic setting from the Late Sinian to the Early Cambrian, during which time the Tongwan tectonic event established the paleogeomorphic framework of this basin (Wang et al. Reference Wang, Jiang, Wang, Lu, Gu, Xu, Yang and Xu2014; Che et al. Reference Che, Tan, Deng and Jin2019; Zhou et al. Reference Zhou, Yang, Ji, Zhou and Zhang2020). This tectonic event caused the episodic uplift of the crust, and each portion of this basin underwent varying degrees of uplift and subsidence; furthermore, the platform region underwent several episodes of denudation, which occurred in varying degrees. Moreover, under the influence of the extensional regime, the Deyang-Anyue Rift Tough developed in the western area, and the region as a whole exhibited a north–south-oriented uplift and depression pattern (Liu et al. Reference Liu, Deng, Jansa, Zhong, Sun, Song, Wang, Wu, Li and Tian2017; Jin et al. Reference Jin, Li, Zhu, Dai, Jiang, Wu, Li and Yang2020; Li et al. Reference Li, He, Li, Li, Wo, Li and Huang2020). The Deyang-Anyue Rift Trough formed due to the early tectonic event and entered a stage of compensatory deposition. The basin was filled with a set of thick-bedded deposits dominated by shales whose sedimentary provenance indicated that they originated from the west and north (Liu et al. Reference Liu, Liu, Li and Liu2020; Zhao et al. Reference Zhao, Hu, Wang, Li, Tan, She, Zhang, Qiao and Wang2020; Wang et al. Reference Wang, Wang, Yan, Zhang, Li and Ma2021).

During the deposition of the Canglangpu Formation, the amplitude of vertical tectonic event decreased considerably, the uplift and depression pattern began to disappear, and the basin paleogeomorphology gradually transformed from the pattern of alternating uplift and depression to that of a shelf with a gentle slope from west to east. The Canglangpu Formation, which consists of sandy shale mixed with limestone and dolostone, was deposited in this environment. During the Middle-Late Cambrian, this area was characterized by semi-restricted and restricted lagoon; the seawater receded and the paleo-uplift further developed during this time. From the Douposi Formation, the depositional environment gradually changed to a carbonate platform (Figs. 1, 2; Fu et al. Reference Fu, Hu, Xu, Zhao, Shi and Zeng2020; Li et al. Reference Li, Chen, Yan, Dai, Xi and He2021; Zhang et al. Reference Zhang, Wang, Zhang, Wei, Wang, Zhang, Ma, Wei, He, Ma and Zhu2022).

The Sichuan Basin is dominated by carbonate deposits; it was covered by a wide epicontinental sea from the Early to the Late Ordovician (Zhu et al. Reference Zhu, Zhang, Liu, Xing, He, Zhang and Liu2018; He et al. Reference He, Wang and Chen2019; Yang et al. Reference Yang, Zuo, Fu, Qiu, Li, Zhang, Zheng and Zhang2022). Owing to the Guangxi tectonic event, the convergence of the block intensified, and the Yangtze Block was subducted and compressed by the Cathaysia Block in the southeast (Ge et al. Reference Ge, Mou, Yu, Liu, Men and He2019; Wang et al. Reference Wang, Li, Wang, Jiang, Chen, Ma and Dai2019; Huang et al. Reference Huang, He, Li, Li, Zhang and Chen2020). The surrounding paleo-lands of the Sichuan Basin were uplifted. The Qianzhong Paleo-land was connected with Xuefeng Paleo-land. The Kangdian and Chuanzhong paleo-lands were expanded. At this juncture, the passive continental margin began to transform into a foreland basin, low-energy and undercompensated depositional basins enclosed by uplifts began to form within the plate (Wang et al. Reference Wang, Li, Wang, Jiang, Chen, Ma and Dai2019; Men et al. Reference Men, Mou, Ge and Wang2020; Lu et al. Reference Lu, Qiu, Zhang, Li and Tao2021). Lithofacies analysis indicated that the carbonate deposits were replaced by terrigenous clastic deposits. The early limestone deposits of the Baota and Linxiang formations were overlain by the black shale deposits of the Wufeng and Longmaxi formations from the Late Ordovician to the Early Silurian (Figs. 1, 2; Chen et al. Reference Chen, Rong, Li and Boucot2004; Liang et al. Reference Liang, Jiang, Yang and Wei2012; Huang et al. Reference Huang, He, Li, Li, Zhang and Chen2020).

2.b. Stratigraphy

The Cambrian–Ordovician strata in the Sichuan Basin and its adjacent areas differ greatly in different regions. The Cambrian strata are dominated by terrigenous clastic deposits in the west and marine carbonate deposits in the east (Wang et al. Reference Wang, Guan, Feng and Bao2013; Zhang et al. Reference Zhang, Song, Jiang, Jiang, Jia, Huang, Wen, Liu, Xie, Liu, Wang, Shan and Wu2019; Xi et al. Reference Xi, Tang, Zhang, Lash and Ye2022). The thickness of the Cambrian succession is ∼100–1500 m, whereas the strata in the western part of the basin are thinner (∼100–500 m) because of the later denudation. The strata in the central part of the basin have a medium thickness of ∼500–1200 m. The strata in the eastern part of the basin are thicker, reaching ∼1500 m (Liu et al. Reference Liu, Tan, Li, Cao and Luo2018; Li et al. Reference Li, Li, Li, Liu, Su and Yan2022; Wang et al. Reference Wang, Wang and Zeng2022). The western area contains the Lower Cambrian Dengying, Qiongzhusi, Canglangpu and Longwangmiao formations, the Middle Cambrian Gaotai Formation and the Upper Cambrian Xixiangchi Formation from bottom to top. Thick layers of shale, clastic rock and various carbonate rocks have been deposited (Yang et al. Reference Yang, Xie, Wei, Liu, Zeng, Xie and Jin2012; Gu et al. Reference Gu, Yin, Yuan, Bo, Liang, Zhang and Zhang2015; Gao et al. Reference Gao, Li, Lash, Yan, Zhou and Xiao2021).

The Ordovician strata have inherited the characteristics of the Cambrian succession, with the depositional basement being high in the west and low in the east, and the sediments being coarse in the west and fine in the east. The stratigraphic thickness of the Ordovician succession is less than that of the Cambrian succession. The stratigraphic thickness of the Ordovician succession is ∼0–800 m; the Ordovician strata have undergone denudation, especially in the western part of the basin (Wang et al. Reference Wang, Dong, Huang, Li and Wang2016; Zhu et al. Reference Zhu, Zhang, Liu, Xing, He, Zhang and Liu2018; Yang et al. Reference Yang, Zuo, Fu, Qiu, Li, Zhang, Zheng and Zhang2022). The western area contains the Lower Ordovician Tongzi and Honghuayuan formations, the Middle Ordovician Meitan and Shizipu formations and the Upper Ordovician Baota, Linxiang and Wufeng formations from bottom to top. A succession of carbonate rocks, mixtites and shales has been deposited here (Figs. 1, 2; Yang et al. Reference Yang, Xie, Wei, Liu, Zeng, Xie and Jin2012; Zhu et al. Reference Zhu, Chen, Liu, Shi, Wu, Luo, Yang, Yang and Zou2021; Miao et al. Reference Miao, Pei, Su, Sheng, Feng, Jiang, Liang and Hong2022).

2.c. Carbonate microfacies and depositional environments

Several depositional environments, such as restricted platform, open platform and platform margin, are seen in the Cambrian–Ordovician system (Yang et al. Reference Yang, Xie, Wei, Liu, Zeng, Xie and Jin2012; Li et al. Reference Li, Tan, Zhao, Liu, Xia and Luo2013; Zhang et al. Reference Zhang, Li, Li, Kiessling and Wang2016; Zeng et al. Reference Zeng, Zhao, Xu, Fu, Hu, Wang and Li2018). The restricted platform can be divided into three subtypes (tidal flat, lagoon and intraplatform shoal); it is mainly developed in the Lower Cambrian Longwangmiao Formation, the Middle Cambrian Gaotai Formation and the Upper Cambrian Xixiangchi Formation. The rocks of this depositional environment primarily consist of light grey-dark grey micritic dolomite, sandy dolomite and argillaceous dolomite, along with doloarenite, dolorudite, oolitic dolomite and gypsum dolomite (Li et al. Reference Li, Yu and Deng2012; Liu et al. Reference Liu, Tan, Li, Cao and Luo2018; Wang et al. Reference Wang, Wang and Zeng2022).

The open platform, which is developed in the Cambrian–Ordovician system, can be divided into the intraplatform shoal and intershoal marine subtypes. The deposits consist of medium-thick stratified light grey and grey micritic limestone, oolitic limestone, argillaceous limestone and intraclastic and bioclastic limestone. The intraplatform shoal subtypes can be divided into sand shoals, oolitic shoals and bioclastic shoals. The intershoal marine subtypes is a relatively low-energy region between intraplatform shoals of the open platform. The sedimentary rocks are dominated by grey and dark grey thin to medium-thick stratified micritic limestone, along with argillaceous limestone, mud-bearing limestone and bioclastic micritic limestone. Moreover, horizontal bedding is developed and foraminifers, bivalves, gastropods and other biogenic fossils are seen (Yang et al. Reference Yang, Xie, Wei, Liu, Zeng, Xie and Jin2012; Li et al. Reference Li, Fan, Jia, Lu, Zhang, Li and Deng2019; Ren et al. Reference Ren, Zhong, Gao, Sun, Peng, Zheng and Qiu2019).

The platform margin is mainly developed in the Ordovician and is distributed along the eastern margin of the Sichuan Basin. The beds are thicker than those of other belts, and the deposits in this region primarily consist of oolitic limestone, oolitic dolomite, micrite dolomite, arenaceous limestone and small amounts of micritic limestone. The platform margin shoal often shows a convex up shape in the vertical plane because of its rapid growth (Figs. 1, 2; Zhao et al. Reference Zhao, Shen, Zhou, Wang and Lu2014; Zhao et al. Reference Zhao, Wei, Yang, Mo, Xie, Su, Liu, Zeng and Wu2017; Gu et al. Reference Gu, Lonergan, Zhai, Zhang and Lu2021).

3. Sampling and methods

3.a. Field methods and sample collection

A total of nine field sites in the Sichuan Basin [the Liujiachang (LJ), Fandian (FD), Yankong (YK), Yangsiqiao (YS), Yangjiaping (YJ), Honghuayuan (HH), Jinfoshan (JF), Nanshanping (NS) and Yanhe (YH) outcrops] were investigated (Fig, 1b). A total of 390 samples were collected at ∼17 m intervals through the 1130 m thick Shuijingtuo-Linxiang formations at the LJ site, the 650 m thick Qiongzhusi-Xixiangchi formations at the FD site, the 820 m thick Niutitang-Maotianba formations at the YK site, the 270 m thick Shuijingtuo-Sanyoudong formations at the YS site, the 2330 m thick Niutitang-Maotianba formations at the YJ site, the 440 m thick Tongzi-Wufeng formations at the HH site, the 300 m thick Tongzi-Wufeng formations at the JF site, the 520 m thick Tongzi-Baota formations at the NS site and the 170 m thick Tongzi-Wufeng formations at the YH site (Fig. 2). Detailed field descriptions were made at each site, and numerous measurements and outcrop photographs were obtained. Thin sections of the samples collected at each site were prepared for petrographic analysis (Table S1).

3.b. Microfacies analysis

A total of 390 outcrop samples were prepared for thin-section analysis and examined on a standard petrographic microscope (Carl Zeiss Axio Scope A1) using transmitted light microscopy (Table S1). The samples were impregnated with blue resin to highlight porosity and stained with Alizarin Red S for carbonate mineral determination. Mineral identification procedures followed the Rock Thin-Section Identification Standard SY/T 5368-2016 (Luo et al. Reference Luo, Shao, Yan, Wang, Wang, Yang, Wang, Song, Cui, Wang and Man2016). Grain content was calculated by point counting using a 20 × 30 grid (n = 600 observations per sample). For particulate sediments (i.e. grainstones), sediment properties such as grain size, roundness and sorting were quantified (Tables S2–S5; Zhou et al. Reference Zhou, Jiang, Quaye, Duan, Hu, Liu and Han2018; Hu et al. Reference Hu, Zhang, Jiang, Wang and Han2021; Tang et al. Reference Tang, Hu, Dan, Han and Liu2022; Hu et al. Reference Hu, Han, Tian, Fu, Ma and Algeo2023b). Samples were evaluated using standard descriptive and interpretative criteria (Wilson et al. Reference Wilson, Tucker, Crevello, Sarg, Read and Tucker1990; Wright, Reference Wright1992; Tucker & Wright, Reference Tucker and Wright2009; Flügel, Reference Flügel2013). Sedimentary differentiation analysis conducted in the present study was based on observations of lithology, bedding, sedimentary textures and grain types (including size, roundness and sorting properties) in outcrops and thin sections.

3.c. Magnetic fabric analysis

A total of 1399 fresh samples for magnetic fabric analysis were collected at ∼5 m intervals using a portable mini-core drill (D026-C) and an insertable magnetic compass. Magnetic samples were taken from all nine field sites (LJ = 274, FD = 140, YK = 149, YS = 133, YJ = 137, HH = 139, JF = 144, NS = 135 and YH = 148) (Fig. 1b; Table S1). Each core sample had a diameter of 25 mm and was trimmed to a length of 22 mm to maintain a uniform sample volume. After preparation, the magnetic susceptibility of each sample was measured using a magnetic susceptibility metre [HKB-1 (High-accuracy Kappa Bridge-1); field strength: 300 A/m; field frequency: 920 Hz; power: AC, 220 V/110 V, 50/60 Hz and 15 W; sensitivity: 2 × 10⁻¹² m³] with an automated sample handling system. Each sample was measured three times along orthogonal planes.

AMS analyses are used to study variations in the magnetic susceptibility field of a sample within a three-dimensional (3D) orthogonal framework (Lagroix & Banerjee, Reference Lagroix and Banerjee2004; Zhang et al. Reference Zhang, Kravchinsky, Zhu and Yue2010; Zhao et al. Reference Zhao, Hu, Han, Dong and Yuan2023). The AMS of a sample is typically reported in terms of K_max, K_int and K_min values, representing the lengths of the maximum, intermediate and minimum principal axes of the 3D AMS ellipsoid, respectively; D-K_max, D-K_int and D-K_min values, representing their respective declinations; and I-K_max, I-K_int and I-K_min values, representing their respective inclinations. Superposition of ferromagnetic, paramagnetic and diamagnetic grain properties yields the total AMS signal (Zhu et al. Reference Zhu, Liu and Jackson2004; Nawrocki et al. Reference Nawrocki, Gozhik, Lanczont, Panczyk, Komar, Bogucki, Williams and Czupyt2018).

The values of K_max, K_int and K_min can be combined in various ways to describe the ellipsoid shape and features of the magnetic fabric of a sample (Jelinek, Reference Jelinek1981; Lagroix & Banerjee, Reference Lagroix and Banerjee2004; Gong et al. Reference Gong, Zhang, Yue, Zhang and Li2015). The magnetic parameters developed for this purpose are as follows:

(1)

$${\rm{Lineation}}\left( {\rm{L}} \right) = {{\rm{K}}_{{\rm{max}}}}/{{\rm{K}}_{{\rm{int}}}}\;$$

(2)

$${\rm{Foliation}}\left( {\rm{F}} \right) = {{\rm{K}}_{{\rm{int}}}}/{{\rm{K}}_{{\rm{min}}}}$$

(3)

$${\rm{Degree\ of\ anisotropy}}\left( {\rm{P}} \right) = {{\rm{K}}_{{\rm{max}}}}/{{\rm{K}}_{{\rm{min}}}}$$

(4)

$${\rm{Shape\ factor}}\left( {\rm{T}} \right) = (2\eta 2 - \eta 1 - \eta 3)/(\eta 1 - \eta 3)$$

where η1, η2 and η3 are ln (K_max), ln (K_int) and ln (K_min), respectively.

The parameters F₁₂ and F₂₃, which are used to evaluate the statistical significance of the lineation and the foliation, were determined following the technique of Lagroix and Banerjee (Reference Lagroix and Banerjee2004) using (1) epsilon ϵ₁₂, the half-angle uncertainty of K_max in the plane joining K_max and K_int, and (2) epsilon ϵ₂₃, the half-angle uncertainty of K_int in the plane joining K_int and K_min. All of the above parameters were calculated using the Safyr and Anisoft software packages (Constable & Tauxe, Reference Constable and Tauxe1990).

The geographic orientations of the principal AMS axes were plotted on stereonets for visualization. The sample set was then screened to isolate the most significant K_max declination using the technique of Lagroix and Banerjee (Reference Lagroix and Banerjee2004) and Zhu et al. (Reference Zhu, Liu and Jackson2004). All D-K_max with F₁₂ < 4 and ϵ₁₂ > 22.5° were rejected to eliminate noise. Rejection of samples with F₁₂ < 4 yielded a confidence ratio of 1.0 for the intermediate and minimum susceptibility axes of the lineation axis, and rejection of samples with ϵ₁₂ > 22.5° yielded a confidence ratio of 1.0 for the maximum and intermediate susceptibility axes in the foliation plane. I-K_min was another parameter used in screening AMS data; values of I-K_min > 70° generally correspond to undisturbed (low degree of reworking) sediments with an oblate magnetic fabric (Lagroix & Banerjee, Reference Lagroix and Banerjee2004; Nawrocki et al. Reference Nawrocki, Gozhik, Lanczont, Panczyk, Komar, Bogucki, Williams and Czupyt2018; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b).

4. Results

4.a. Sedimentary differentiation

Previous studies reported on the general microfacies analysis of Cambrian–Ordovician carbonate facies in the YCP (e.g. Zou et al. Reference Zou, Fang, Zhang and Zhang2017; Tan et al. Reference Tan, Shi, Tian, Wang and Wang2018; Zhang-SC et al. Reference Zhang, He, Hu, Mi, Ma, Liu and Tang2018; Zhai et al. Reference Zhai, Li, Jiao, Wang, Liu, Xu, Wang, Chen and Guo2019; Fu et al. Reference Fu, Hu, Xu, Zhao, Shi and Zeng2020; Gao et al. Reference Gao, Li, Lash, Yan, Zhou and Xiao2021). The present study focused on oolitic and intraclastic grainstones with the aim of identifying sedimentary differentiation due to prevailing wind directions.

4.a.1. Oolitic grainstone

The northwestern, central and southeastern portions of the YCP exhibited differences in the thicknesses of oolitic grainstone beds as well as in the size and sorting of ooids (Fig. 3; Tables S2, S3). The northwestern margin is characterized by moderately sorted to well-sorted ooids that accumulated in a northwest-facing windward environment. In contrast, the southeastern margin shows poorly to moderately sorted sediments (Table 1; Fig. 3). The energy levels at the northwestern margin were relatively high, whereas those at the southeastern margin were relatively low. The southeastern margin has greater bedding thicknesses and ooid grain diameters, and it is inferred to have possessed the optimal growth environment for ooids (Zhang-YY et al. Reference Zhang, Li, Wang and Munnecke2017; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a).

Fig. 3. Diagram summarizing the variations in the approximate bedding thickness (a), ooid size (b) and sorting (c) of Cambrian–Ordovician oolitic grainstone.

Table 1. Comparison of the main sedimentary characteristics for different Cambrian–Ordovician sites

4.a.2. Intraclastic grainstone

Quantitative measurements of intraclastic grainstone samples from the Cambrian–Ordovician indicated differences in the thickness of intraclastic grainstone beds, as well as in the size, roundness and sorting of intraclasts among the northwestern, central and southeastern regions of the YCP (Fig. 4; Tables S4, S5). The northwestern margin is characterized by moderately sorted to well-sorted and sub-angular to rounded intraclasts that accumulated in a northwest-facing windward environment. In contrast, the southeastern margin shows poorly to moderately sorted sediments with angular to sub-rounded grains (Table 1; Fig. 4). The energy levels at the northwestern margin were relatively high, whereas those at the southeastern margin were relatively low (Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b; Hu et al. Reference Hu, Han, Ma, Wang, Zhao and Sun2023a).

Fig. 4. Diagram summarizing the variations in approximate bedding thickness (a), intraclast size (b), roundness (c) and sorting (d) of the Cambrian–Ordovician intraclastic grainstone.

4.b. AMS

Most of the samples collected at all locales in the present study exhibited an oblate magnetic fabric (Fig. 5a, b, Figures S2–S3; Lagroix & Banerjee, Reference Lagroix and Banerjee2004; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b). The observed ratio of the degree of anisotropy (P) to foliation (F) was consistent with a subordinate role for lineation (L) (Fig. 5c, Figure S4). These features are typical of sediments deposited by wind or water currents (Lagroix & Banerjee, Reference Lagroix and Banerjee2004; Nawrocki et al. Reference Nawrocki, Gozhik, Lanczont, Panczyk, Komar, Bogucki, Williams and Czupyt2018). Inverse relationships were observed between ϵ₁₂ and L (Fig. 5d, Figure S5) and between ϵ₂₃ and F (Fig. 5e, Figure S6), which resulted from increased measurement errors for weak lineations and foliations, respectively. In contrast, the absence of a correlation between ϵ₁₂ and F suggested that the lineation and foliation subfabrics were probably defined by the orientations of different minerals (Fig. 5f, g, Figures S7–S8).

Fig. 5. Relationships between the AMS parameters of (a) P and T, (b) F and L, (c) P and F, (d) L and ϵ₁₂, (e) F and ϵ₂₃, (f) F and ϵ₁₂, and (g) ϵ₁₂ and F₁₂ for the Ordovician units at the YH outcrop (n = 148). The results for other outcrops (i.e. LJ, FD, YK, YS, YJ, HH, JF and NS) are provided in Figures S2–S8.

4.b.1. AMS for each Cambrian series

The robustness of statistical calculations was increased by limiting calculations to Cambrian samples, for which F₁₂ > 4, ϵ₁₂ < 22.5° and I-K_min > 70° (Table 2; Fig. 6, Figure S9). The screened sample sets of each Cambrian series yielded K_max values with different preferred orientations for each of the five target outcrops (Table 3; Fig. 6, Figure S9). A centroid statistical approach was applied in the Safyr and Anisoft software to assess the distribution of K_max values for the screened sample set of each outcrop. This approach was used to determine the dominant orientations. When the inclination is not considered, the centroid statistical diagram only magnifies variations in K_max declinations. The centroid D-K_max values of the Lower Cambrian samples were 116° at LJ, 119° at FD, 117° at YK, 115° at YS and 113° at YJ. The centroid D-K_max values of the Middle Cambrian samples were 141° at LJ, 146° at FD, 143° at YK, 149° at YS and 146° at YJ. The centroid D-K_max values of the Upper Cambrian samples were 158° at LJ, 159° at FD, 160° at YK, 161° at YS and 157° at YJ (modern coordinates; Table 3; Fig. 6, Figure S9).

Table 2. The robustness of statistical calculations was increased by limiting calculations to Cambrian samples, for which F₁₂ > 4, ϵ₁₂ < 22.5° and I-K_min > 70°. Detailed information is provided in Figs. 6, S9

Fig. 6. Equal-area projections (modern coordinates) of AMS principal axes of selected samples (according to criteria for which F12 > 4, ϵ12 < 22.5°, and I-K_min > 70°) for each Cambrian series from the five outcrops. (a) Lower Cambrian at the LJ outcrop (n = 26). (b) Lower Cambrian at the FD outcrop (n = 21). (c) Lower Cambrian at the YK outcrop (n = 27). (d) Lower Cambrian at the YS outcrop (n = 37). (e) Lower Cambrian at the YJ outcrop (n = 31). (f) Middle Cambrian at the LJ outcrop (n = 26). (g) Middle Cambrian at the FD outcrop (n = 29). (h) Middle Cambrian at the YK outcrop (n = 31). (i) Middle Cambrian at the YS outcrop (n = 30). (j) Middle Cambrian at the YJ outcrop (n = 31). (k) Upper Cambrian at the LJ outcrop (n = 35). (l) Upper Cambrian at the FD outcrop (n = 23). (m) Upper Cambrian at the YK outcrop (n = 29). (n) Upper Cambrian at the YS outcrop (n = 24). (o) Upper Cambrian at the YJ outcrop (n = 20). K_max = maximum principal axes of the 3D AMS ellipsoid; K_min = minimum principal axes of the 3D AMS ellipsoid; and D-K_max = declination of the maximum principal axes of the 3D AMS ellipsoid.

Table 3. Maximum AMS axis (K_max) with different preferred orientations and centroid D-K_max values for each of the five study outcrops for each Cambrian series. Detailed information is provided in Fig. 6

4.b.2. AMS for each Ordovician series

Statistical robustness was ensured in the present study by limiting calculations to samples of the Ordovician, for which F₁₂ > 4, ϵ₁₂ < 22.5° and I-K_min > 70° (Table 4; Fig. 7, Figure S10). The screened sample sets of each Ordovician series yielded K_max values with different preferred orientations for each of the five target outcrops (Table 5; Fig. 7, Figure S10). The centroid D-K_max values of the Lower Ordovician samples were 169° at LJ, 168° at HH, 170° at JF, 171° at NS and 167° at YH. The centroid D-K_max values of the Middle Ordovician samples were 136° at LJ, 139° at HH, 138° at JF, 140° at NS and 142° at YH. The centroid D-K_max values of the Upper Ordovician samples were 90° at LJ, 89° at HH, 88° at JF, 93° at NS and 95° at YH (modern coordinates; Table 5; Fig. 7, Figure S10).

Table 4. The robustness of statistical calculations was increased by limiting calculations to Ordovician samples, for which F₁₂ > 4, ϵ₁₂ < 22.5° and I-K_min > 70°. Detailed information is provided in Figs. 7, S10

Fig. 7. Equal-area projections (modern coordinates) of AMS principal axes of selected samples (according to criteria for which F12 > 4, ϵ12 < 22.5° and I-K_min > 70°) for each Ordovician series from the five outcrops. (a) Lower Ordovician at the LJ outcrop (n = 24). (b) Lower Ordovician at the HH outcrop (n = 23). (c) Lower Ordovician at the JF outcrop (n = 22). (d) Lower Ordovician at the NS outcrop (n = 30). (e) Lower Ordovician at the YH outcrop (n = 32). (f) Middle Ordovician at the LJ outcrop (n = 30). (g) Middle Ordovician at the HH outcrop (n = 36). (h) Middle Ordovician at the JF outcrop (n = 40). (i) Middle Ordovician at the NS outcrop (n = 24). (j) Middle Ordovician at the YH outcrop (n = 23). (k) Upper Ordovician at the LJ outcrop (n = 24). (l) Upper Ordovician at the HH outcrop (n = 28). (m) Upper Ordovician at the JF outcrop (n = 30). (n) Upper Ordovician at the NS outcrop (n = 31). (o) Upper Ordovician at the YH outcrop (n = 18). K_max = maximum principal axes of the 3D AMS ellipsoid; K_min = minimum principal axes of the 3D AMS ellipsoid; and D-K_max = declination of maximum principal axes of the 3D AMS ellipsoid.

Table 5. Maximum AMS axis (K_max) with different preferred orientations and centroid D-K_max values for each of the five study outcrops for each Ordovician series. Detailed information is provided in Fig. 7

5. Discussion

5.a. Qualitative reconstruction of paleowind directions

Carbonate platform sediments undergo sedimentary differentiation under the action of long-term prevailing winds. Patterns of wind-related facies have been studied in several modern marine systems, among which the best-studied are the those in the Bahamas and Florida Keys (Kindler & Strasser, Reference Kindler and Strasser2000; Rankey et al. Reference Rankey, Riegl and Steffen2006; Rankey & Reeder, Reference Rankey and Reeder2011). The dominant winds in the Bahamas are the northeasterly trade winds, and coral reefs form on the margins of the northeast-facing windward platform (e.g. eastern side of Andros Island). In contrast, oolitic shoals accumulate on the southwest-facing leeward margins (Principaud et al. Reference Principaud, Mulder, Gillet and Borgomano2015; Dravis & Wanless, Reference Dravis and Wanless2017). Patterns of wind-related facies have also been studied in ancient carbonate platforms. For example, paleowind analysis was conducted on the Cambrian–Ordovician Shanganning Carbonate Platform of the North China Craton (Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b). The study utilized a combination of microfacies analysis and AMS data to evaluate wind-related controls and documented metazoan reefs consisting of corals, stromatoporoids and sponges on the windward platform margin and oolitic grainstones and microbial reefs on the leeward margin (Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b).

The sedimentary differentiation of oolitic and intraclastic grainstones described above qualitatively indicates the general wind direction in the present study (Table 1; Figs. 3, 4). The spatial distribution of specific microfacies and sediment types shows a polarity across the YCP, which helps distinguish between the windward and leeward margins of the platform. Oolitic sands dominate the leeward margins of platforms, and water in these areas originates from the platform interior and is relatively warm and partially degassed (Principaud et al. Reference Principaud, Mulder, Gillet and Borgomano2015; Dravis & Wanless, Reference Dravis and Wanless2017; Zhang-YY et al. Reference Zhang, Li, Wang and Munnecke2017; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b; Hu et al. Reference Hu, Han, Ma, Wang, Zhao and Sun2023a). Therefore, the observed polarity of facies across the YCP is consistent with strong paleowinds, presumably the trade winds, which originate from the northwest (modern coordinates).

5.b. Quantitative reconstruction of paleowind directions

AMS can be used to determine the prevailing paleowind directions (Zhang et al. Reference Zhang, Kravchinsky, Zhu and Yue2010; Nawrocki et al. Reference Nawrocki, Gozhik, Lanczont, Panczyk, Komar, Bogucki, Williams and Czupyt2018; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b; Hu et al. Reference Hu, Han, Ma, Deng and Zhao2022; Hu et al. Reference Hu, Han, Ma, Wang, Zhao and Sun2023a). Examples in previous studies include the reconstruction of the route of the paleomonsoon along a west-to-east transect in the Chinese Loess Plateau using AMS (Zhang et al. Reference Zhang, Kravchinsky, Zhu and Yue2010), and reconstruction of paleowind directions and sources of detrital material archived in the Roxolany loess section, southern Ukraine (Nawrocki et al. Reference Nawrocki, Gozhik, Lanczont, Panczyk, Komar, Bogucki, Williams and Czupyt2018). The AMS orientations of the study samples could be explained based on a model of strong unidirectional flow (Fig. S1B; Tarling & Hrouda, Reference Tarling and Hrouda1993; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b), which demonstrated the greatest agreement with the distribution of data in the current study (Figs. 6, 7). Most grains in this model were oriented parallel to the unidirectional flow (Fig. S1B; Tarling & Hrouda, Reference Tarling and Hrouda1993; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b). However, paleocurrent directions antipodal to (i.e. 180° away from) the estimated current vectors cannot be excluded given the shallowness of the observed AMS K_max inclinations (< 20°; Figs. 6, 7; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b; Hu et al. Reference Hu, Han, Ma, Wang, Zhao and Sun2023a).

Two opposite paleowind directions can be roughly determined based on the AMS results obtained herein. The paleomagnetic results of the Early, Middle and Late Cambrian were 116° ± 52°, 145° ± 57° and 159° ± 62°, respectively (Table 3; Fig. 6), with paleowind directions of 116° ± 52°, 145° ± 57° and 159° ± 62°, respectively, or 296° ± 52°, 325° ± 57° and 339° ± 62°, respectively (modern coordinates; Fig. 8a–c). The paleomagnetic results of the Early, Middle and Late Ordovician were 169° ± 70°, 139° ± 73° and 91° ± 68°, respectively (Table 5; Fig. 7), with paleowind directions of 169° ± 70°, 139° ± 73° and 91° ± 68°, respectively, or 349° ± 70°, 319° ± 73° and 271° ± 68°, respectively (modern coordinates; Fig. 8d–f). The final quantitative prevailing paleowind directions can be determined by combining information on the sedimentary differentiation (see section 5.a). The paleowind directions of the Early, Middle and Late Cambrian were 296° ± 52°, 325° ± 57° and 339° ± 62°, respectively (modern coordinates; Fig .8a–c). The paleowind directions of the Early, Middle and Late Ordovician were 349° ± 70°, 319° ± 73° and 271° ± 68°, respectively (modern coordinates; Fig. 8d–f).

Fig. 8. Comprehensively interpretative rose diagram showing the prevailing paleowind directions for each epoch of the Cambrian–Ordovician. (a) Early Cambrian. (b) Middle Cambrian. (c) Late Cambrian. (d) Early Ordovician. (e) Middle Ordovician. (f) Late Ordovician.

Marine carbonate platforms are generally located within the trade winds belt at low latitudes (such as The Bahamas, Great Barrier Reef and Shanganning Carbonate Platform). These areas were affected by the prevailing paleowind direction throughout the year, with sedimentary differentiation following a specific trend (Orpin & Ridd, Reference Orpin and Ridd2012; Puga-Bernabéu et al. Reference Puga-Bernabéu, Webster, Beaman and Guilbaud2013; Principaud et al. Reference Principaud, Mulder, Gillet and Borgomano2015; Dravis & Wanless, Reference Dravis and Wanless2017; Hu et al. Reference Hu, Zhang, Jiang, Wang, Han and Algeo2020a, Reference Hu, Zhang, Tian, Wang, Han, Wang, Li, Feng, Han and Algeo2020b). Although sedimentary differentiation cannot be used to quantitatively reconstruct the paleowind directions, it can be used to determine the approximate orientation. Although AMS cannot be used to determine the general orientation of paleowind direction, its quantitative ability can compensate for the non-quantification of sedimentary differentiation. The complementarity of sedimentary differentiation and AMS allows for the quantitative determination of the prevailing paleowind directions, thereby providing a theoretical basis for the study of Cambrian–Ordovician paleoclimate in this area.

5.c. Significance of paleowind directions for paleogeography

The prevailing paleowind direction acted to regulate sedimentary differentiation in the three zones of the YCP, which had important paleogeographic implications. The YCP was located in the low latitudes during the Cambrian–Ordovician (Huang et al. Reference Huang, Zhu, Otofuji and Yang2000; Popov et al. Reference Popov, Bassett, Zhemchuzhnikov, Holmer and Klishevich2009; Nardin et al. Reference Nardin, Goddéris, Donnadieu, Hir, Blakey, Pucéat and Aretz2011; Torsvik & Cocks, Reference Torsvik, Cocks, Harper and Servais2013; Cocks & Torsvik, Reference Cocks and Torsvik2021; Harper et al. Reference Harper, Cascales-Miñana, Kroeck and Servais2021). However, its exact position remains a matter of debate due to the lack of sufficient palaeomagnetic data. The determination of the position of the YCP would refine the current knowledge of the prevailing wind direction by as much as 90°, since trade winds in the Northern Hemisphere blow from northeast to southwest, whereas those in the Southern Hemisphere blow from southeast to northwest (Kajtar et al. Reference Kajtar, Santoso, McGregor, England and Baillie2018; Helfer et al. Reference Helfer, Nuijens, De Roode and Siebesma2020, Reference Helfer, Nuijens and Dixit2021). The present geographic orientation of the Yangtze Block indicates that the prevailing paleowind directions were from the northwest, north and west (Tables 3, 5; Fig. 8). Therefore, the Yangtze Block has rotated after the Ordovician.

The prevailing wind directions of the trade winds belt change slightly for different positions. The prevailing wind direction is nearly south (155°–180°) when positioned far from the Equator in the Southern Hemisphere and nearly east (90°–115°) when near the Equator in the Southern Hemisphere (Kajtar et al. Reference Kajtar, Santoso, McGregor, England and Baillie2018; Helfer et al. Reference Helfer, Nuijens, De Roode and Siebesma2020, Reference Helfer, Nuijens and Dixit2021). The YCP was located at latitudes of ∼24°S, ∼28°S, ∼21°S during the Late Cambrian, Early Ordovician and Middle Ordovician, respectively (Torsvik & Cocks, Reference Torsvik, Cocks, Harper and Servais2013; Cocks & Torsvik, Reference Cocks and Torsvik2021). The relevant paleowind directions are ∼170°, ∼177° and ∼165°; all directions are approximate values, but all are slightly less than 180° (paleo-coordinates). This study provides evidence for the paleogeography of the YCP during the Cambrian–Ordovician in terms of the prevailing paleowind directions over the YCP and the trade winds in the Northern and Southern hemispheres (southeast wind in the Southern Hemisphere and northeast wind in the Northern Hemisphere). For the Early Cambrian, the samples collected for this study were concentrated in the upper part of the Lower Cambrian, so the measurement results only correspond to the late stage of the Early Cambrian. For the Late Ordovician, the samples collected for this study were concentrated in the lower part of the Upper Ordovician, so the measurement results only correspond to the early stage of the Late Ordovician.

The current position of the YCP would indicate that its paleowind directions were 296° ± 52° during the Early Cambrian, 325° ± 57° during the Middle Cambrian, 339° ± 62° during the Late Cambrian, 349° ± 70° during the Early Ordovician, 319° ± 73° during the Middle Ordovician and 271° ± 68° during the Late Ordovician (Tables 3, 5; Fig. 8). This conclusion is consistent with the most recent knowledge of paleogeography (e.g. Torsvik & Cocks, Reference Torsvik, Cocks, Harper and Servais2013; Cocks & Torsvik, Reference Cocks and Torsvik2021): (1) the YCP was located in the Southern Hemisphere (∼14°S), and the prevailing paleowind direction was ∼133° (paleo-coordinates) during the Early Cambrian. The plate has rotated ∼197° counterclockwise since the Early Cambrian, so the paleowind direction was ∼296° in modern coordinates; (2) the YCP was located at ∼18°S, and the prevailing paleowind direction was ∼156° (paleo-coordinates) during the Middle Cambrian. The plate has rotated ∼191° counterclockwise since the Middle Cambrian, so the paleowind direction was ∼325° in modern coordinates; (3) the YCP was located at ∼24°S and the prevailing paleowind direction was ∼168° (paleo-coordinates) during the Late Cambrian. The plate has rotated ∼189° counterclockwise since the Late Cambrian, so the paleowind direction was ∼339° in modern coordinates; (4) the YCP was located at ∼28°S and the prevailing paleowind direction was ∼173° (paleo-coordinates) during the Early Ordovician. The plate has rotated ∼184° counterclockwise since the Early Ordovician, so the paleowind direction was ∼349° in modern coordinates; (5) the YCP was located at ∼21°S, and the prevailing paleowind direction was ∼165° (paleo-coordinates) during the Middle Ordovician. The plate has rotated ∼206° counterclockwise since the Middle Ordovician, so the paleowind direction was ∼319° in modern coordinates; and (6) the YCP was located at ∼16°S and the prevailing paleowind direction was ∼136° (paleo-coordinates) during the Late Ordovician. The plate has rotated ∼225° counterclockwise since the Late Ordovician, so the paleowind direction was ∼271° in modern coordinates (Torsvik & Cocks, Reference Torsvik, Cocks, Harper and Servais2013; Cocks & Torsvik, Reference Cocks and Torsvik2021; Fig. 9).

Fig. 9. Relationship between present and Cambrian-Ordovician geographic orientations of the YCP. Paleowind orientations of the YCP are shown in modern coordinate (left) and paleo-coordinate (right) frameworks. Data are for Early Cambrian (a, b), Middle Cambrian (c, d), Late Cambrian (e, f), Early Ordovician (g, h), Middle Ordovician (i, j) and Late Ordovician (k, l). The prevailing wind directions for each Cambrian-Ordovician series are based on the AMS results from Tables 3 and 5 as well as Figs. 6, 7. Syn-and post-Cambrian and Ordovician tectonic rotations are shown by tapered grey arrows.

The determination of paleowind directions can be of geological significance for ancient carbonate platforms or basins. For example, as shown in the present study, the paleogeography of a plate can be constrained using wind directions.

6. Conclusions

The YCP was located in the low-latitude trade winds belt during the Cambrian–Ordovician and was affected by the prevailing wind directions. Analysis of the sedimentary differentiation of carbonate microfacies and AMS on the platform indicated that the paleowind directions over the YCP during the Early, Middle and Late Cambrian were 296° ± 52°, 325° ± 57° and 339° ± 62° respectively, whereas those during the Early, Middle and Late Ordovician were 349° ± 70°, 319° ± 73° and 271° ± 68°, respectively (modern coordinates). The present study quantitatively reconstructed the prevailing paleowind directions over the YCP through an analysis of sedimentary differentiation and AMS. The results of the present study can provide a reference for the study of the paleoclimate of the YCP.

The present study provided evidence for the location of the YCP during the Cambrian–Ordovician through the corresponding relationship between the prevailing paleowind directions over the YCP and the trade winds in the Northern and Southern hemispheres. The YCP was located at ∼14°S, ∼18°S and ∼24°S during the Early, Middle and Late Cambrian, respectively; corresponding values for the Early, Middle and Late Ordovician were ∼28°S, ∼21°S and ∼16°S, respectively. The results of the present study can provide a reference for the study of the paleogeography of the YCP.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S0016756823000286

Data availability

All relevant data used for the research described in this article are included in the article and/or its supplementary files. Upon the request to the corresponding author (majinghui10@163.com) or first author (huchenlin@tom.com), the data are available.

Acknowledgements

We thank Wenxuan Sun, Zhiqiang Fu and Lingfeng Zhao for their help in data analysis. This study was supported by Natural Science Foundation of Xinjiang Uygur Autonomous Region (2020D01C064; 2020D01C037) and Natural Science Foundation of China (42062010). The authors would like to thank MJEditor (www.mjeditor.com) for its linguistic assistance during the preparation of this manuscript. Thanks are also extended to Geological Magazine Editor Emese Bordy and two anonymous reviewers for their constructive comments.

Conflicts of interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

References

Aria, C and Caron, JB (2019) A middle Cambrian arthropod with chelicerae and proto-book gills. Nature 573, 586–89. doi: 10.1038/s41586-019-1525-4.CrossRef Google Scholar PubMed

Chang, HJ, Chu, XL, Feng, LJ, Huang, J and Chen, YL (2018) Marine redox stratification on the earliest Cambrian (ca. 542–529 Ma) Yangtze Platform. Palaeogeography, Palaeoclimatology, Palaeoecology 504, 75–85. doi: 10.1016/j.palaeo.2018.05.007.CrossRef Google Scholar

Che, ZQ, Tan, XC, Deng, JT and Jin, MD (2019) The characteristics and controlling factors of facies-controlled coastal eogenetic karst: insights from the fourth member of Neoproterozoic Dengying formation, Central Sichuan Basin, China. Carbonates and Evaporites 34, 1771–83. doi: 10.1007/s13146-019-00524-0.CrossRef Google Scholar

Chen, X, Rong, JY, Li, Y and Boucot, AJ (2004) Facies patterns and geography of the Yangtze region, South China, though the Ordovician and Silurian transition. Palaeogeography, Palaeoclimatology, Palaeoecology 204, 353–72. doi: 10.1016/S0031-0182(03)00736-3.Google Scholar

Cheng, SH, Li, B, Zhang, K, Liu, WW, Peng, J, Hou, MC, Wen, M, Xia, QS, Wang, X, Liu, XX, Zhong, L, Huang, YZ, Liu, YY, Yuan, MH and Yao, Y (2020) Study on the mechanism of organic matter enrichment in early Cambrian marine shales in the lower Yangtze area, South China: an example using well jxy1. Geofluids 2020. doi: 10.1155/2020/2460302.CrossRef Google Scholar

Cheng, XY, Ding, WL, Pan, L, Zou, YT, Li, YT, Yin, YX and Ding, SH (2022) Geometry and kinematics characteristics of strike-slip fault zone in complex structure area: a case study from the South No. 15 strike-slip fault zone in the Eastern Sichuan Basin, China. Frontiers in Earth Science 10, 922664. doi: 10.3389/feart.2022.922664.CrossRef Google Scholar

Cocks, LRM and Torsvik, TH (2021) Ordovician palaeogeography and climate change. Gondwana Research 100, 53–72. doi: 10.1016/j.gr.2020.09.008.CrossRef Google Scholar

Constable, C and Tauxe, L (1990) The bootstrap for magnetic susceptibility tensors. Journal of Geophysical Research: Solid Earth 95, 8383–95. doi: 10.1029/JB095iB06p08383.CrossRef Google Scholar

Dalziel, IW (2014) Cambrian transgression and radiation linked to an Iapetus-Pacific oceanic connection? Geology 42, 979–82. doi: 10.1130/G35886.1.CrossRef Google Scholar

Dong, L, Han, CC, Santosh, M, Qiu, YK, Liu, G, Ma, JH, He, H and Hu, CL (2022) Factors influencing the pore structure and gas-bearing characteristics of Shales: insights from the Longmaxi formation, Southern Sichuan Basin and Northern Yunnan-Guizhou Depression, China. Geofluids. doi: 10.1155/2022/1692516.CrossRef Google Scholar

Dravis, JJ and Wanless, HR (2017) Impact of strong easterly trade winds on carbonate petroleum exploration-relationships developed from Caicos Platform, southeastern Bahamas. Marine and Petroleum Geology 85, 272–300. doi: 10.1016/j.marpetgeo.2017.04.010.CrossRef Google Scholar

Fang, X, Li, WJ, Zhang, JP, Song, YY and Zhang, YD (2020) Paleo-environmental changes during the Middle–Late Ordovician transition on the Yangtze Platform, South China and their ecological implications. Palaeogeography, Palaeoclimatology, Palaeoecology 560, 109991. doi: 10.1016/j.palaeo.2020.109991.CrossRef Google Scholar

Flügel, E (2013) Classification―A Name for Your Sample, Chapter 8 in Microfacies of Carbonate Rocks: Analysis, Interpretation and Application: Springer Science & Business Media, pp. 339–64. doi: 10.1007/978-3-662-08726-8.Google Scholar

Fu, QL, Hu, SY, Xu, ZH, Zhao, WZ, Shi, SY and Zeng, HL (2020) Depositional and diagenetic controls on deeply buried Cambrian carbonate reservoirs: Longwangmiao formation in the Moxi–Gaoshiti area, Sichuan Basin, southwestern China. Marine and Petroleum Geology 117, 104318. doi: 10.1016/j.marpetgeo.2020.104318.CrossRef Google Scholar

Gao, P, Li, SJ, Lash, GG, Yan, DT, Zhou, Q and Xiao, XM (2021) Stratigraphic framework, redox history, and organic matter accumulation of an Early Cambrian intraplatfrom basin on the Yangtze Platform, South China. Marine and Petroleum Geology 130, 105095. doi: 10.1016/j.marpetgeo.2021.105095.CrossRef Google Scholar

Ge, XY, Mou, CL, Yu, Q, Liu, W, Men, X and He, JL (2019) The geochemistry of the sedimentary rocks from the Huadi No. 1 well in the Wufeng-Longmaxi formations (Upper Ordovician-Lower Silurian), South China, with implications for paleoweathering, provenance, tectonic setting and paleoclimate. Marine and Petroleum Geology 103, 646–60. doi: 10.1016/j.marpetgeo.2018.12.040.CrossRef Google Scholar

Gong, HJ, Zhang, R, Yue, LP, Zhang, YX and Li, JX (2015) Magnetic fabric from Red clay sediments in the Chinese Loess Plateau. Scientific Reports 5, 1–6. doi: 10.1038/srep09706.CrossRef Google Scholar PubMed

Gu, ZD, Lonergan, L, Zhai, XF, Zhang, BM and Lu, WH (2021) The formation of the Sichuan Basin, South China, during the Late Ediacaran to Early Cambrian. Basin Research 33, 2328–57. doi: 10.1111/bre.12559.CrossRef Google Scholar

Gu, ZD, Yin, JF, Yuan, M, Bo, DM, Liang, DX, Zhang, H and Zhang, L (2015) Accumulation conditions and exploration directions of natural gas in deep subsalt Sinian-Cambrian System in the eastern Sichuan Basin, SW China. Petroleum Exploration and Development 42, 152–66. doi: 10.1016/S1876-3804(15)30002-1.CrossRef Google Scholar

Han, CC, Tian, JJ, Hu, CL, Liu, HL, Wang, WF, Huan, ZP and Feng, S (2020) Lithofacies characteristics and their controlling effects on reservoirs in buried hills of metamorphic rocks: a case study of late Paleozoic units in the Aryskum depression, South Turgay Basin, Kazakhstan. Journal of Petroleum Science and Engineering 191, 107–37. doi: 10.1016/j.petrol.2020.107137.CrossRef Google Scholar

Harper, DA, Cascales-Miñana, B, Kroeck, DM and Servais, T (2021) The palaeogeographical impact on the biodiversity of marine faunas during the Ordovician radiations. Global and Planetary Change 207, 103665. doi: 10.1016/j.gloplacha.2021.103665.CrossRef Google Scholar

He, L, Wang, YP and Chen, DF (2019) Geochemical features of sedimentary environment and paleoclimate during Late Ordovician to Early Silurian in southern Sichuan Basin. Geochimica 48, 555–66. doi: 10.19700/j.0379-1726.2019.06.004.Google Scholar

Helfer, KC, Nuijens, L, De Roode, SR and Siebesma, AP (2020) How wind shear affects trade-wind cumulus convection. Journal of Advances in Modeling Earth Systems 12, e2020MS002183. doi: 10.1029/2020MS002183.CrossRef Google Scholar PubMed

Helfer, KC, Nuijens, L and Dixit, VV (2021) The role of shallow convection in the momentum budget of the trades from large-eddy-simulation hindcasts. Quarterly Journal of the Royal Meteorological Society 147, 2490–505. doi: 10.1002/qj.4035.CrossRef Google Scholar

Hoyal Cuthill, JF, Guttenberg, N and Budd, GE (2020) Impacts of speciation and extinction measured by an evolutionary decay clock. Nature 588, 636–41. doi: 10.1038/s41586-020-3003-4.CrossRef Google Scholar PubMed

Hu, CL, Han, CC, Ma, JH, Deng, L and Zhao, LF (2022) Paleowind directions over the Tarim Block during the Mesoproterozoic, Northwestern China. Minerals 12, 1435. doi: 10.3390/min12111435.CrossRef Google Scholar

Hu, CL, Han, CC, Ma, JH, Wang, WF, Zhao, FY and Sun, WX (2023a) Reconstruction of paleowind directions during the Cambrian-Ordovician in the Tarim Basin, Northwestern China. Palaeogeography, Palaeoclimatology, Palaeoecology 609, 111316. doi: 10.1016/J.PALAEO.2022.111316.CrossRef Google Scholar

Hu, CL, Han, CC, Tian, JJ, Fu, ZQ, Ma, JH and Algeo, TJ (2023b) Lithofacies and diagenetic controls on tight silty and sandy Upper Triassic reservoirs of the Heshui Oil Field (Ordos Basin, North China). SPE Reservoir Evaluation & Engineering 26, 19–37. doi: 10.2118/214289-PA.Google Scholar

Hu, CL, Zhang, YF, Feng, DY, Wang, M, Jiang, ZX and Jiao, CW (2017) Flume tank simulation on depositional mechanism and controlling factors of beach-bar reservoirs. Journal of Earth Science 28, 1153–62. doi: 10.1007/s12583-016-0929-4.CrossRef Google Scholar

Hu, CL, Zhang, YF, Jiang, ZX, Wang, M and Han, C (2021) Development of large-scale sand bodies in a fault-bounded lake basin: Pleistocene-Holocene Poyang Lake, Southern China. Journal of Paleolimnology 65, 407–28. doi: 10.1007/s10933-021-00179-9.CrossRef Google Scholar

Hu, CL, Zhang, YF, Jiang, ZX, Wang, M, Han, C and Algeo, TJ (2020a) Tectonic and paleogeographic controls on development of the Early–Middle Ordovician Shanganning carbonate platform, Ordos Basin, North China. AAPG Bulletin 104, 565–93. doi: 10.1306/06121918175.CrossRef Google Scholar

Hu, CL, Zhang, YF, Tian, JJ, Wang, WF, Han, CC, Wang, HC, Li, X, Feng, S, Han, C and Algeo, TJ (2020b) Influence of paleo-Trade Winds on facies patterns of the Cambrian Shanganning carbonate platform, North China. Palaeogeography, Palaeoclimatology, Palaeoecology 552, 109556. doi: 10.1016/j.palaeo.2019.109556.CrossRef Google Scholar

Huang, BC, Zhu, RX, Otofuji, Y and Yang, ZY (2000) The early Paleozoic paleogeography of the North China block and the other major blocks of China. Chinese Science Bulletin 45, 1057–8. doi: 10.1007/BF02887174.CrossRef Google Scholar

Huang, HY, He, DF, Li, D, Li, YQ, Zhang, WK and Chen, JJ (2020) Geochemical characteristics of organic-rich shale, Upper Yangtze Basin: implications for the Late Ordovician–Early Silurian orogeny in South China. Palaeogeography, Palaeoclimatology, Palaeoecology 554, 109822. doi: 10.1016/j.palaeo.2020.109822.CrossRef Google Scholar

Jelinek, V (1981) Characterization of the magnetic fabric of rocks. Tectonophysics 79, T63–7. doi: 10.1016/0040-1951(81)90110-4.CrossRef Google Scholar

Jin, CS, Li, C, Algeo, TJ, Planavsky, NJ, Cui, H, Yang, XL, Zhao, YL, Zhang, XL and Xie, SS (2016) A highly redox-heterogeneous ocean in South China during the early Cambrian (∼ 529–514 Ma): implications for biota-environment co-evolution. Earth and Planetary Science Letters 441, 38–51. doi: 10.1016/j.epsl.2016.02.019.CrossRef Google Scholar

Jin, MD, Li, BS, Zhu, X, Dai, LC, Jiang, ZL, Wu, H, Li, H and Yang, PY (2020) Characteristics and main controlling factors of reservoirs in the fourth member of Sinian Dengying formation in Yuanba and its peripheral area, northeastern Sichuan Basin, SW China. Petroleum Exploration and Development 47, 1172–82. doi: 10.1016/S1876-3804(20)60127-1.CrossRef Google Scholar

Kajtar, JB, Santoso, A, McGregor, S, England, MH and Baillie, Z (2018) Model under-representation of decadal Pacific trade wind trends and its link to tropical Atlantic bias. Climate Dynamics 50, 1471–84. doi: 10.1007/s00382-017-3699-5.CrossRef Google Scholar

Karlstrom, K, Hagadorn, J, Gehrels, G, Matthews, W, Schmitz, M, Madronich, L, Mulder, J, Pecha, M, Giesler, D and Crossey, L (2018) Cambrian Sauk transgression in the Grand Canyon region redefined by detrital zircons. Nature Geoscience 11, 438–43. doi: 10.1038/s41561-018-0131-7.CrossRef Google Scholar

Kindler, P and Strasser, A (2000) Palaeoclimatic significance of co-occurring wind-and water-induced sedimentary structures in the last-interglacial coastal deposits from Bermuda and the Bahamas. Sedimentary Geology 131, 1–7. doi: 10.1016/S0037-0738(99)00123-2.CrossRef Google Scholar

Kröger, B (2018) Changes in the latitudinal diversity gradient during the Great Ordovician Biodiversification event. Geology 46, 127–30. doi: 10.1130/G39587.1.CrossRef Google Scholar

Lagroix, F and Banerjee, SK (2002) Paleowind directions from the magnetic fabric of loess profiles in central Alaska. Earth and Planetary Science Letters 195, 99–112. doi: 10.1016/S0012-821X(01)00564-7.CrossRef Google Scholar

Lagroix, F and Banerjee, SK (2004) The regional and temporal significance of primary Aeolian magnetic fabrics preserved in Alaskan loess. Earth and Planetary Science Letters 225, 379–95. doi: 10.1016/j.epsl.2004.07.003.3.CrossRef Google Scholar

Lee, JH and Riding, R (2018) Marine oxygenation, lithistid sponges, and the early history of Paleozoic skeletal reefs. Earth-Science Reviews 181, 98–121. doi: 10.1016/j.earscirev.2018.04.003.CrossRef Google Scholar

Li, G, Li, ZQ, Li, D, Liu, HL, Su, GP and Yan, S (2022) Basement fault control on the extensional process of a basin: a case study from the Cambrian–Silurian of the Sichuan Basin, South-west China. Geological Journal. doi: 10.1002/gj.4492.CrossRef Google Scholar

Li, L, Tan, XC, Zhao, LZ, Liu, H, Xia, JW and Luo, B (2013) Prediction of thin shoal-facies reservoirs in the carbonate platform interior: a case from the Cambrian Xixiangchi Group of the Weiyuan area, Sichuan Basin. Petroleum Exploration and Development 40, 359–66. doi: 10.1016/S1876-3804(13)60043-9.CrossRef Google Scholar

Li, QJ, Li, Y, Wang, JP and Kiessling, W (2015) Early Ordovician lithistid sponge–Calathium reefs on the Yangtze Platform and their paleoceanographic implications. Palaeogeography, Palaeoclimatology, Palaeoecology 425, 84–96. doi: 10.1016/j.palaeo.2015.02.034.CrossRef Google Scholar

Li, W, Fan, R, Jia, P, Lu, YZ, Zhang, ZJ, Li, X and Deng, SH (2019) Sequence stratigraphy and lithofacies paleogeography of the Middle–Upper Cambrian Xixiangchi Group in the Sichuan Basin and its adjacent area, SW China. Petroleum Exploration and Development 46, 238–52. doi: 10.1016/S1876-3804(19)60005-4.CrossRef Google Scholar

Li, W, Yu, HQ and Deng, HB (2012) Stratigraphic division and correlation and sedimentary characteristics of the Cambrian in central-southern Sichuan Basin. Petroleum Exploration and Development 39, 725–35. doi: 10.1016/S1876-3804(12)60097-4.CrossRef Google Scholar

Li, YD, Chen, YL, Yan, W, Dai, RX, Xi, C and He, Y (2021) Research on sedimentary evolution characteristics of Cambrian Canglangpu formation, Sichuan Basin. Natural Gas Geoscience 32, 1334–46 (in Chinese with English abstract).Google Scholar

Li, YQ, He, DF, Li, D, Li, SJ, Wo, YJ, Li, CX and Huang, HY (2020) Ediacaran (Sinian) palaeogeographic reconstruction of the Upper Yangtze area, China, and its tectonic implications. International Geology Review 62, 1485–509. doi: 10.1080/00206814.2019.1655670.CrossRef Google Scholar

Liang, C, Jiang, ZX, Yang, YT and Wei, XJ (2012) Shale lithofacies and reservoir space of theg Wufeng–Longmaxi formation, Sichuan Basin, China. Petroleum Exploration and Development 39, 736–43. doi: 10.1016/S1876-3804(12)60098-6.CrossRef Google Scholar

Liu, H, Tan, XC, Li, YH, Cao, J and Luo, B (2018) Occurrence and conceptual sedimentary model of Cambrian gypsum-bearing evaporites in the Sichuan Basin, SW China. Geoscience Frontiers 9, 1179–91. doi: 10.1016/j.gsf.2017.06.006.CrossRef Google Scholar

Liu, JL, Liu, KY, Li, CW and Liu, WJ (2020) Tectono-sedimentary evolution of the Late Ediacaran to early Cambrian trough in central Sichuan Basin, China: New insights from 3D stratigraphic forward modelling. Precambrian Research 350, 105826. doi: 10.1016/j.precamres.2020.105826.CrossRef Google Scholar

Liu, SG, Deng, B, Jansa, L, Zhong, Y, Sun, W, Song, JM, Wang, GZ, Wu, J, Li, ZW and Tian, YH (2017) The early cambrian mianyang-changning intracratonic sag and its control on petroleum accumulation in the Sichuan Basin, China. Geofluids 2017. doi: 10.1155/2017/6740892.CrossRef Google Scholar

Liu, SG, Yang, Y, Deng, B, Zhong, Y, Wen, L, Sun, W, Li, ZW, Jansa, L, Li, JX, Song, JM, Zhang, XH and Peng, HL (2021) Tectonic evolution of the sichuan basin, southwest China. Earth-Science Reviews 213, 103470. doi: 10.1016/j.earscirev.2020.103470.CrossRef Google Scholar

Lu, B, Qiu, Z, Zhang, BH, Li, J and Tao, HF (2021) Geological significance of rare earth elements in marine shale during the Late Ordovician–Early Silurian in Sichuan Basin, South China. Geological Journal 56, 1821–40. doi: 10.1002/gj.4027.CrossRef Google Scholar

Luo, Z, Shao, HM, Yan, YX, Wang, RH, Wang, P, Yang, Z, Wang, YK, Song, BR, Cui, JG, Wang, LY and Man, L (2016) Rock Thin-Section Identification Standard of SY/T 5368-2016. China: National Energy Administration, pp. 43 (In Chinese).Google Scholar

Men, X, Mou, CL, Ge, XY and Wang, YC (2020) Geochemical characteristics of siliceous rocks of Wufeng Formation in the Late Ordovician, South China: assessing provenance, depositional environment, and formation model. Geological Journal 55, 2930–50. doi: 10.1002/gj.3553.CrossRef Google Scholar

Miao, ZS, Pei, YW, Su, N, Sheng, SZ, Feng, B, Jiang, H, Liang, H and Hong, HT (2022) Spatial and temporal evolution of the Sinian and its implications on petroleum exploration in the Sichuan Basin, China. Journal of Petroleum Science and Engineering 210, 110036. doi: 10.1016/j.petrol.2021.110036.CrossRef Google Scholar

Nardin, E, Goddéris, Y, Donnadieu, Y, Hir, GL, Blakey, RC, Pucéat, E and Aretz, M (2011) Modeling the early Paleozoic long-term climatic trend. Bulletin 123, 1181–92. doi: 10.1130/B30364.1.Google Scholar

Nawrocki, J, Gozhik, P, Lanczont, M, Panczyk, M, Komar, M, Bogucki, A, Williams, IS and Czupyt, Z (2018) Palaeowind directions and sources of detrital material archived in the Roxolany loess section (southern Ukraine). Palaeogeography, Palaeoclimatology, Palaeoecology 496, 121–35. doi: 10.1016/j.paleo.2018.01.028.CrossRef Google Scholar

Orpin, AR and Ridd, PV (2012) Exposure of inshore corals to suspended sediments due to wave-resuspension and river plumes in the central Great Barrier Reef: a reappraisal. Continental Shelf Research 47, 55–67. doi: 10.1016/j.csr.2012.06.013.CrossRef Google Scholar

Peters, SE and Gaines, RR (2012) Formation of the ‘Great Unconformity’ as a trigger for the Cambrian explosion. Nature 484, 363–6. doi: 10.1038/nature10969.CrossRef Google Scholar PubMed

Popov, LE, Bassett, MG, Zhemchuzhnikov, VG, Holmer, LE and Klishevich, IA (2009) Gondwanan faunal signatures from early Palaeozoic terranes of Kazakhstan and Central Asia: evidence and tectonic implications. Geological Society, London, Special Publications 325, 23–64. doi: 10.1144/SP325.3.CrossRef Google Scholar

Principaud, M, Mulder, T, Gillet, H and Borgomano, J (2015) Large-scale carbonate submarine mass-wasting along the northwestern slope of the Great Bahama Bank (Bahamas): morphology, architecture, and mechanisms. Sedimentary Geology 317, 27–42. doi: 10.1016/j.sedgeo.2014.10.008.CrossRef Google Scholar

Puga-Bernabéu, A, Webster, JM, Beaman, RJ and Guilbaud, V (2013) Variation in canyon morphology on the Great Barrier Reef margin, north-eastern Australia: the influence of slope and barrier reefs. Geomorphology 191, 35–50. doi: 10.1016/j.geomorph.2013.03.001.CrossRef Google Scholar

Rankey, EC and Reeder, SL (2011) Holocene oolitic marine sand complexes of the Bahamas. Journal of Sedimentary Research 81, 97–117. doi: 10.2110/jsr.2011.10.CrossRef Google Scholar

Rankey, EC, Riegl, B and Steffen, K (2006) Form, function and feedbacks in a tidally dominated ooid shoal, Bahamas. Sedimentology 53, 1191–210. doi: 10.1111/j.1365-3091.2006.00807.x.CrossRef Google Scholar

Rees, AI and Woodall, WA (1975) The magnetic fabric of some laboratory-deposited sediments. Earth and Planetary Science Letters 25, 121–30. doi: 10.1016/0012-821x(75)90188-0.CrossRef Google Scholar

Ren, Y, Zhong, DK, Gao, CL, Sun, HT, Peng, H, Zheng, XW and Qiu, C (2019) Origin of dolomite of the lower Cambrian Longwangmiao Formation, eastern Sichuan Basin, China. Carbonates and Evaporites 34, 471–90. doi: 10.1007/s13146-017-0409-7.CrossRef Google Scholar

Shi, CH, Cao, J, Selby, D, Tan, XC, Luo, B and Hu, WX (2020) Hydrocarbon evolution of the over-mature Sinian Dengying reservoir of the Neoproterozoic Sichuan Basin, China: insights from Re–Os geochronology. Marine and Petroleum Geology 122, 104726. doi: 10.1016/j.marpetgeo.2020.104726.CrossRef Google Scholar

Stigall, AL, Edwards, CT, Freeman, RL and Rasmussen, CM (2019) Coordinated biotic and abiotic change during the Great Ordovician Biodiversification event: Darriwilian assembly of early Paleozoic building blocks. Palaeogeography, Palaeoclimatology, Palaeoecology 530, 249–70. doi: 10.1016/j.palaeo.2019.05.034.CrossRef Google Scholar

Tan, Q, Shi, ZJ, Tian, YM, Wang, Y and Wang, CC (2018) Origin of ooids in ooidal-muddy laminites: a case study of the lower Cambrian Qingxudong Formation in the Sichuan Basin, South China. Geological Journal 53, 1716–27. doi: 10.1002/gj.2995.CrossRef Google Scholar

Tang, YN, Hu, CL, Dan, SH, Han, CC and Liu, ZM (2022) Depositional model for the early Triassic Braided River Delta and controls on oil reservoirs in the Eastern Junggar Basin, Northwestern China. Minerals 12, 1409. doi: 10.3390/min12111409.CrossRef Google Scholar

Tarling, DH and Hrouda, F (1993) The Magnetic Anisotropy of Rocks. London: Chapman and Hall, pp. 220.Google Scholar

Torsvik, TH and Cocks, LRM (2013) New global palaeogeographical reconstructions for the Lower Palaeozoic and their generation. In Early Palaeozoic Biogeography and Geography (eds Harper, DAT and Servais, T, 38, pp. 5–24. Geological Society of London, Memoir. doi: 10.1144/M38.2.Google Scholar

Tucker, ME and Wright, VP (2009) Carbonate Sedimentology. New York: John Wiley & Sons, 481 pp.Google Scholar

Wang, FY, Guan, J, Feng, WP and Bao, LY (2013) Evolution of overmature marine shale porosity and implication to the free gas volume. Petroleum Exploration and Development 40, 819–24. doi: 10.1016/S1876-3804(13)60111-1.CrossRef Google Scholar

Wang, Q, Wang, XZ and Zeng, XY (2022) Research on reservoir characteristics and main controlling factors of Longwangmiao formation of Cambrian in Sichuan Basin. Frontiers in Earth Science 503. doi: 10.3389/feart.2022.885637.Google Scholar

Wang, Y, Wang, SY, Yan, HJ, Zhang, YJ, Li, JZ and Ma, DB (2021) Microbial carbonate sequence architecture and depositional environments of Member IV of the Late Ediacaran Dengying Formation, Gaoshiti–Moxi area, Sichuan Basin, Southwest China. Geological Journal 56, 3992–4015. doi: 10.1002/gj.4146.CrossRef Google Scholar

Wang, YM, Dong, DZ, Huang, JL, Li, XJ and Wang, SF (2016) Guanyinqiao Member lithofacies of the Upper Ordovician Wufeng formation around the Sichuan Basin and the significance to shale gas plays, SW China. Petroleum Exploration and Development 43, 45–53. doi: 10.1016/S1876-3804(16)30005-2.CrossRef Google Scholar

Wang, YM, Li, XJ, Wang, H, Jiang, S, Chen, B, Ma, J and Dai, B (2019) Developmental characteristics and geological significance of the bentonite in the Upper Ordovician Wufeng–Lower Silurian Longmaxi formation in eastern Sichuan Basin, SW China. Petroleum Exploration and Development 46, 687–700. doi: 10.1016/S1876-3804(19)60226-0.CrossRef Google Scholar

Wang, ZC, Jiang, H, Wang, TS, Lu, WH, Gu, ZD, Xu, AN, Yang, Y and Xu, ZH (2014) Paleo-geomorphology formed during Tongwan tectonization in Sichuan Basin and its significance for hydrocarbon accumulation. Petroleum Exploration and Development 41, 338–45. doi: 10.1016/S1876-3804(14)60038-0.CrossRef Google Scholar

Wilson, JL, Tucker, ME, Crevello, PD, Sarg, JR and Read, JF (1990) Basement structural controls on Mesozoic carbonate facies in northeastern Mexico―a review. In Carbonate Platforms: Facies, Sequences and Evolution (ed Tucker, ME), pp. 235–56. New York: John Wiley & Sons.Google Scholar

Wood, R, Liu, AG, Bowyer, F, Wilby, PR, Dunn, FS, Kenchington, CG, Hoyal Cuthill, JF, Mitchell, EG and Penny, A (2019) Integrated records of environmental change and evolution challenge the Cambrian explosion. Nature Ecology & Evolution 3, 528–38. doi: 10.1038/s41559-019-0821-6.CrossRef Google Scholar PubMed

Wright, VP (1992) A revised classification of limestones. Sedimentary Geology 76, 177–85. doi: 10.1016/0037-0738(92)90082-3.CrossRef Google Scholar

Wu, YW, Tian, H, Li, J, Li, TF and Ji, S (2021) Reconstruction of oceanic redox structures during the Ediacaran-Cambrian transition in the Yangtze Block of South China: Implications from Mo isotopes and trace elements. Precambrian Research 359, 106181. doi: 10.1016/j.precamres.2021.106181.CrossRef Google Scholar

Xi, ZD, Tang, SH, Zhang, SH, Lash, GG and Ye, YP (2022) Controls of marine shale gas accumulation in the eastern periphery of the Sichuan Basin, South China. International Journal of Coal Geology 251, 103939. doi: 10.1016/j.coal.2022.103939.CrossRef Google Scholar

Yang, MH, Zuo, YH, Fu, XD, Qiu, L, Li, WZ, Zhang, JY, Zheng, ZY and Zhang, JZ (2022) Paleoenvironment of the Lower Ordovician Meitan Formation in the Sichuan Basin and adjacent Areas, China. Minerals 12, 75. doi: 10.3390/min12010075.CrossRef Google Scholar

Yang, W, Xie, WR, Wei, GQ, Liu, MC, Zeng, FY, Xie, ZY and Jin, H (2012) Sequence lithofacies paleogeography, favorable reservoir distribution and exploration zones of the Cambrian and Ordovician in Sichuan Basin, China. Acta Petrolei Sinica 33, 21–34 (in Chinese with English abstract). doi: 10.7623/syxb2012S2003.Google Scholar

Zeng, HL, Zhao, WZ, Xu, ZH, Fu, QL, Hu, SY, Wang, ZC and Li, BH (2018) Carbonate seismic sedimentology: a case study of Cambrian Longwangmiao Formation, Gaoshiti-Moxi area, Sichuan Basin, China. Petroleum Exploration and Development 45, 830–9. doi: 10.1016/S1876-3804(18)30086-7.CrossRef Google Scholar

Zhai, GY, Li, J, Jiao, Y, Wang, YF, Liu, GH, Xu, Q, Wang, C, Chen, R and Guo, XB (2019) Applications of chemostratigraphy in a characterization of shale gas Sedimentary Microfacies and predictions of sweet spots—taking the Cambrian black shales in Western Hubei as an example. Marine and Petroleum Geology 109, 547–60. doi: 10.1016/j.marpetgeo.2019.06.045.CrossRef Google Scholar

Zhai, LN, Wu, CD, Ye, YT, Zhang, SC and Wang, YZ (2018) Fluctuations in chemical weathering on the Yangtze Block during the Ediacaran–Cambrian transition: Implications for paleoclimatic conditions and the marine carbon cycle. Palaeogeography, Palaeoclimatology, Palaeoecology 490, 280–92. doi: 10.1016/j.palaeo.2017.11.006.CrossRef Google Scholar

Zhang, K, Song, Y, Jiang, S, Jiang, ZX, Jia, CZ, Huang, YZ, Wen, M, Liu, WW, Xie, XL, Liu, TL, Wang, PF, Shan, CA and Wu, YH (2019) Mechanism analysis of organic matter enrichment in different sedimentary backgrounds: a case study of the Lower Cambrian and the Upper Ordovician-Lower Silurian, in Yangtze region. Marine and Petroleum Geology 99, 488–97. doi: 10.1016/j.marpetgeo.2018.10.044.CrossRef Google Scholar

Zhang, PY, Wang, YL, Zhang, XJ, Wei, ZF, Wang, G, Zhang, T, Ma, H, Wei, JY, He, W, Ma, XY and Zhu, CX (2022) Carbon, oxygen, and strontium isotopic and elemental characteristics of the Cambrian Longwangmiao formation in South China: Paleoenvironmental significance and implications for carbon isotope excursions. Gondwana Research 106, 174–90. doi: 10.1016/j.gr.2022.01.008.CrossRef Google Scholar

Zhang, R, Kravchinsky, VA, Zhu, RX and Yue, LP (2010) Paleomonsoon route reconstruction along a W–E transect in the Chinese Loess Plateau using the anisotropy of magnetic susceptibility: summer monsoon model. Earth and Planetary Science Letters 299, 436–46. doi: 10.1016/j.epsl.2010.09.026.CrossRef Google Scholar

Zhang, SC, He, K, Hu, GY, Mi, JK, Ma, QS, Liu, KY and Tang, YC (2018) Unique chemical and isotopic characteristics and origins of natural gases in the Paleozoic marine formations in the Sichuan Basin, SW China: isotope fractionation of deep and high mature carbonate reservoir gases. Marine and Petroleum Geology 89, 68–82. doi: 10.1016/j.marpetgeo.2017.02.010.CrossRef Google Scholar

Zhang, YF, Hu, CL, Wang, M, Ma, MF, Wang, XM and Jiang, ZX (2018) A quantitative sedimentary model for the modern lacustrine beach bar (Qinghai Lake, Northwest China). Journal of Paleolimnology 59, 279–96. doi: 10.1007/s10933-016-9930-2.CrossRef Google Scholar

Zhang, YF, Hu, CL, Wang, XM, Wang, M, Jiang, ZX and Li, JJ (2017) An improved method of laser particle size analysis and its application in identification of lacustrine tempestite and beach bar: an example from the Dongying Depression. Journal of Earth Science 28, 1145–52. doi: 10.1007/s12583-016-0930-1.CrossRef Google Scholar

Zhang, YY, Li, QJ, Li, Y, Kiessling, W and Wang, JP (2016) Cambrian to lower Ordovician reefs on the Yangtze platform, South China Block, and their controlling factors. Facies 62, 1–18. doi: 10.1007/s10347-016-0466-8.CrossRef Google Scholar

Zhang, YY, Li, Y, Wang, G and Munnecke, A (2017) Windward and leeward margins of an Upper Ordovician carbonate platform in the Central Tarim Uplift, Xinjiang, northwestern China. Palaeogeography, Palaeoclimatology, Palaeoecology 474, 79–88. doi: 10.1016/j.palaeo.2016.12.040.CrossRef Google Scholar

Zhao, DF, Hu, G, Wang, LC, Li, F, Tan, XC, She, M, Zhang, WJ, Qiao, ZF and Wang, XF (2020) Sedimentary characteristics and origin of dolomitic ooids of the terminal Ediacaran Dengying Formation at Yulin (Chongqing, South China). Palaeogeography, Palaeoclimatology, Palaeoecology 544, 109601. doi: 10.1016/j.palaeo.2020.109601.CrossRef Google Scholar

Zhao, FY, Hu, CL, Han, CC, Dong, YQ and Yuan, QX (2023) Paleocurrent and paleowind direction reconstruction research progress and perspectives: a review. Australian Journal of Earth Sciences. Accepted.CrossRef Google Scholar

Zhao, WZ, Shen, AJ, Zhou, JG, Wang, XF and Lu, JM (2014) Types, characteristics, origin and exploration significance of reef-shoal reservoirs: a case study of Tarim Basin, NW China and Sichuan Basin, SW China. Petroleum Exploration and Development 41, 283–93. doi: 10.1016/S1876-3804(14)60034-3.CrossRef Google Scholar

Zhao, WZ, Wei, GQ, Yang, W, Mo, WL, Xie, WR, Su, N, Liu, MC, Zeng, FY and Wu, SJ (2017) Discovery of Wanyuan-Dazhou Intracratonic Rift and its significance for gas exploration in Sichuan Basin, SW China. Petroleum Exploration and Development 44, 697–707. doi: 10.1016/S1876-3804(17)30081-2.CrossRef Google Scholar

Zheng, SC, Clausen, S, Feng, QL and Servais, T (2020) Review of organic-walled microfossils research from the Cambrian of China: implications for global phytoplankton diversity. Review of Palaeobotany and Palynology 276, 104191. doi: 10.1016/j.revpalbo.2020.104191.CrossRef Google Scholar

Zhou, XW, Jiang, ZX, Quaye, JA, Duan, Y, Hu, CL, Liu, C and Han, C (2018) Ichnology and sedimentology of the trace fossil-bearing fluvial red beds from the lowermost member of the Paleocene Funing formation in the Jinhu Depression, Subei Basin, East China. Marine and Petroleum Geology 99, 393–415. doi: 10.1016/j.marpetgeo.2018.10.032.CrossRef Google Scholar

Zhou, Y, Yang, FL, Ji, YL, Zhou, XF and Zhang, CH (2020) Characteristics and controlling factors of dolomite karst reservoirs of the Sinian Dengying Formation, central Sichuan Basin, southwestern China. Precambrian Research 343, 105708. doi: 10.1016/j.precamres.2020.105708.CrossRef Google Scholar

Zhu, DY, Zhang, DW, Liu, QY, Xing, FC, He, ZL, Zhang, RQ and Liu, ZH (2018) Formation mechanism of dolomite reservoir controlled by fourth-order sequence in an evaporated marine environment–an example from the lower Ordovician Tongzi Formation in the Sichuan Basin. Energy Exploration & Exploitation 36, 620–44. doi: 10.1177/0144598717736630.CrossRef Google Scholar

Zhu, RX, Liu, QS and Jackson, MJ (2004) Paleoenvironmental significance of the magnetic fabrics in Chinese loess-paleosols since the last interglacial (< 130 ka). Earth and Planetary Science Letters 221, 55–69. doi: 10.1016/S0012-821X(04)00103-7.CrossRef Google Scholar

Zhu, YQ, Chen, GS, Liu, Y, Shi, XW, Wu, W, Luo, C, Yang, X, Yang, YR and Zou, YH (2021) Sequence stratigraphy and lithofacies paleogeographic evolution of Katian Stage–Aeronian Stage in southern Sichuan Basin, SW China. Petroleum Exploration and Development 48, 1126–38. doi: 10.1016/S1876-3804(21)60096-4.CrossRef Google Scholar

Zou, H, Fang, Y, Zhang, ST and Zhang, Q (2017) The source of Fengjia and Langxi barite–fluorite deposits in southeastern Sichuan, China: evidence from rare earth elements and S, Sr, and Sm–Nd isotopic data. Geological Journal 52, 470–88. doi: 10.1002/gj.2779.CrossRef Google Scholar

Fig. 1. Regional index map showing the study area. (a) Simplified map of China showing the location of the YCP (after Chen et al.2004). (b) Paleogeographic map of the YCP during the Late Ordovician, showing the outcrop locations used in the present study (after Chen et al.2004). Detailed information of the nine outcrops (LJ, FD, YK, YS, NY, YJ, HH, JF, NS and YH) is provided in Table S1.

Fig. 2. Cambrian–Ordovician stratigraphy in the Sichuan Basin area of the YCP (after Yang et al.2012).

Fig. 3. Diagram summarizing the variations in the approximate bedding thickness (a), ooid size (b) and sorting (c) of Cambrian–Ordovician oolitic grainstone.

Table 1. Comparison of the main sedimentary characteristics for different Cambrian–Ordovician sites

Fig. 4. Diagram summarizing the variations in approximate bedding thickness (a), intraclast size (b), roundness (c) and sorting (d) of the Cambrian–Ordovician intraclastic grainstone.

Fig. 5. Relationships between the AMS parameters of (a) P and T, (b) F and L, (c) P and F, (d) L and ϵ12, (e) F and ϵ23, (f) F and ϵ12, and (g) ϵ12 and F12 for the Ordovician units at the YH outcrop (n = 148). The results for other outcrops (i.e. LJ, FD, YK, YS, YJ, HH, JF and NS) are provided in Figures S2–S8.

Table 2. The robustness of statistical calculations was increased by limiting calculations to Cambrian samples, for which F12 > 4, ϵ12 < 22.5° and I-Kmin > 70°. Detailed information is provided in Figs. 6, S9

Fig. 6. Equal-area projections (modern coordinates) of AMS principal axes of selected samples (according to criteria for which F12 > 4, ϵ12 < 22.5°, and I-Kmin > 70°) for each Cambrian series from the five outcrops. (a) Lower Cambrian at the LJ outcrop (n = 26). (b) Lower Cambrian at the FD outcrop (n = 21). (c) Lower Cambrian at the YK outcrop (n = 27). (d) Lower Cambrian at the YS outcrop (n = 37). (e) Lower Cambrian at the YJ outcrop (n = 31). (f) Middle Cambrian at the LJ outcrop (n = 26). (g) Middle Cambrian at the FD outcrop (n = 29). (h) Middle Cambrian at the YK outcrop (n = 31). (i) Middle Cambrian at the YS outcrop (n = 30). (j) Middle Cambrian at the YJ outcrop (n = 31). (k) Upper Cambrian at the LJ outcrop (n = 35). (l) Upper Cambrian at the FD outcrop (n = 23). (m) Upper Cambrian at the YK outcrop (n = 29). (n) Upper Cambrian at the YS outcrop (n = 24). (o) Upper Cambrian at the YJ outcrop (n = 20). Kmax = maximum principal axes of the 3D AMS ellipsoid; Kmin = minimum principal axes of the 3D AMS ellipsoid; and D-Kmax = declination of the maximum principal axes of the 3D AMS ellipsoid.

Table 3. Maximum AMS axis (Kmax) with different preferred orientations and centroid D-Kmax values for each of the five study outcrops for each Cambrian series. Detailed information is provided in Fig. 6

Table 4. The robustness of statistical calculations was increased by limiting calculations to Ordovician samples, for which F12 > 4, ϵ12 < 22.5° and I-Kmin > 70°. Detailed information is provided in Figs. 7, S10

Fig. 7. Equal-area projections (modern coordinates) of AMS principal axes of selected samples (according to criteria for which F12 > 4, ϵ12 < 22.5° and I-Kmin > 70°) for each Ordovician series from the five outcrops. (a) Lower Ordovician at the LJ outcrop (n = 24). (b) Lower Ordovician at the HH outcrop (n = 23). (c) Lower Ordovician at the JF outcrop (n = 22). (d) Lower Ordovician at the NS outcrop (n = 30). (e) Lower Ordovician at the YH outcrop (n = 32). (f) Middle Ordovician at the LJ outcrop (n = 30). (g) Middle Ordovician at the HH outcrop (n = 36). (h) Middle Ordovician at the JF outcrop (n = 40). (i) Middle Ordovician at the NS outcrop (n = 24). (j) Middle Ordovician at the YH outcrop (n = 23). (k) Upper Ordovician at the LJ outcrop (n = 24). (l) Upper Ordovician at the HH outcrop (n = 28). (m) Upper Ordovician at the JF outcrop (n = 30). (n) Upper Ordovician at the NS outcrop (n = 31). (o) Upper Ordovician at the YH outcrop (n = 18). Kmax = maximum principal axes of the 3D AMS ellipsoid; Kmin = minimum principal axes of the 3D AMS ellipsoid; and D-Kmax = declination of maximum principal axes of the 3D AMS ellipsoid.

Table 5. Maximum AMS axis (Kmax) with different preferred orientations and centroid D-Kmax values for each of the five study outcrops for each Ordovician series. Detailed information is provided in Fig. 7

Hu et al. supplementary material

Tables S1-S6 and Figures S1-S10

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Article contents

Paleo-trade wind directions over the Yangtze Carbonate Platform during the Cambrian–Ordovician, Southern China

Abstract

Keywords

1. Introduction

2. Geological setting

2.a. Tectonic setting

2.b. Stratigraphy

2.c. Carbonate microfacies and depositional environments

3. Sampling and methods

3.a. Field methods and sample collection

3.b. Microfacies analysis

3.c. Magnetic fabric analysis

4. Results

4.a. Sedimentary differentiation

4.a.1. Oolitic grainstone

4.a.2. Intraclastic grainstone

4.b. AMS

4.b.1. AMS for each Cambrian series

4.b.2. AMS for each Ordovician series

5. Discussion

5.a. Qualitative reconstruction of paleowind directions

5.b. Quantitative reconstruction of paleowind directions

5.c. Significance of paleowind directions for paleogeography

6. Conclusions

Supplementary material

Data availability

Acknowledgements

Conflicts of interest

References

Hu et al. supplementary material

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