| [1] | 陈成业. 2021. 台湾国姓中新世菱铁矿结核的沉积特征及生长机制[原文如此][D]. 上海:上海海洋大学. Chen Chengye. 2021. Sedimentary characteristics and growth mechanism of Miocene siderite nodules of the Kuohsing, Taiwan [sic][D]. Shanghai: Shanghai Ocean University. |
| [2] | 陈杨,金鑫,郎咸国,等. 2025. 鄂尔多斯盆地T-OAE时期湖泊硫循环及其地质意义[J]. 沉积学报,43(6):1952-1967. Chen Yang, Jin Xin, Lang Xianguo, et al. 2025. Sulfur cycle change and its geological significance during the Toarcian Oceanic Anoxic Event (T-OAE) in the Ordos Basin[J]. Acta Sedimentologica Sinica, 43(6): 1952-1967. |
| [3] | 冯云鹤. 2014. 鄂尔多斯盆地(内蒙古部分)富县组的发现及其意义[J]. 地层学杂志,38(4):449-453. Feng Yunhe. 2014. The discovery of the Fuxian Formation in the Ordos Basin (Inner Mongolia part) and its implications[J]. Journal of Stratigraphy, 38(4): 449-453. |
| [4] | 葛道凯,杨起,付泽明,等. 1989. 陕北榆林富县组中的遗迹化石及其环境意义[J]. 煤田地质与勘探,17(6):1-3. Ge Daokai, Yang Qi, Fu Zeming, et al. 1989. The trace fossils and depositional environments of Fuxian Formation, Yulin county, northern Shaanxi province[J]. Coal Geology & Exploration, 17(6): 1-3. |
| [5] | 何自新. 2003. 鄂尔多斯盆地演化与油气[M]. 北京:石油工业出版社:66-83. He Zixin. 2003. Evolution and hydrocarbon in Ordos Basin[M]. Beijing: Petroleum Industry Press: 66-83. |
| [6] | 李宝芳,李祯,林畅松,等. 1995. 鄂尔多斯盆地中部下中侏罗统沉积体系和层序地层[M]. 北京:地质出版社:27- 83. Li Baofang, Li Zhen, Lin Changsong, et al. 1995. Depositional systems and sequence stratigraphy of the Lower and Middle Jurassic strata in the middle part of the Ordos Basin[M]. Beijing: Geological Publishing House: 27-83. |
| [7] | 李昌昊,葛禹,金鑫,等. 2022. 鄂尔多斯盆地早侏罗世富县期沉积演化:大洋缺氧事件前后陆地气候变化的响应[J]. 古地理学报,24(4):697-712. Li Changhao, Ge Yu, Jin Xin, et al. 2022. Sedimentological evolution during the Early Jurassic Fuxian period in Ordos Basin: Palaeoclimatic response to Toarcian Oceanic Anoxic Event[J]. Journal of Palaeogeography, 24(4): 697-712. |
| [8] | 李超,程猛, Algeo T J,等. 2015. 早期地球海洋水化学分带的理论预测[J]. 中国科学:地球科学,45(12):1829-1838. Li Chao, Cheng Meng, Algeo T J, et al. 2015. A theoretical prediction of chemical zonation in early oceans (>520 Ma)[J]. Science China Earth Sciences, 45(12): 1829-1838. |
| [9] | 李金虎,张智慧,秦明,等. 2011. 新疆且日克其菱铁矿床稀土元素地球化学特征[J]. 矿产与地质,25(1):69-73. Li Jinhu, Zhang Zhihui, Qin Ming, et al. 2011. Geochemical characteristics of rare earth elements in Qierikeqi siderite deposit of Xinjiang[J]. Mineral Resources and Geology, 25(1): 69-73. |
| [10] | 曲长胜,邱隆伟,杨勇强,等. 2017. 吉木萨尔凹陷芦草沟组碳酸盐岩碳氧同位素特征及其古湖泊学意义[J]. 地质学报,91(3):605-616. Qu Changsheng, Qiu Longwei, Yang Yongqiang, et al. 2017. Carbon and oxygen isotope compositions of carbonatic rock from Permian Lucaogou Formation in the Jimsar Sag, NW China and their paleolimnological significance[J]. Acta Geologica Sinica, 91(3): 605-616. |
| [11] | 桑树勋,郑永飞,张华,等. 2004. 徐州地区下古生界碳酸盐岩的碳、氧同位素研究[J]. 岩石学报,20(3):707-716. Sang Shuxun, Zheng Yongfei, Zhang Hua, et al. 2004. Researches on carbon and oxygen stable isotopes of Lower Paleozoic carbonates in Xuzhou area[J]. Acta Petrologica Sinica, 20(3): 707-716. |
| [12] | 时志强,韩永林,赵俊兴. 2002. 鄂尔多斯盆地早侏罗世富县期冲积扇沉积[J]. 成都理工学院学报,29(4):390-393. Shi Zhiqiang, Han Yonglin, Zhao Junxing. 2002. Fans at the Early Jurassic Fu-xian stage in Ordos Basin[J]. Journal of Chengdu University of Technology, 29(4): 390-393. |
| [13] | 苏玲,朱如凯,崔景伟,等. 2017. 中国湖相碳酸盐岩时空分布与碳氧同位素特征[J]. 古地理学报,19(6):1063-1074. Su Ling, Zhu Rukai, Cui Jingwei, et al. 2017. Spatial-temporal distribution of lacustrine carbonate rocks in China and their carbon and oxygen isotopic characteristics[J]. Journal of Palaeogeography, 19(6): 1063-1074. |
| [14] | 王志鹏. 2017. 中元古代高于庄组三段碳酸盐岩结核的形成环境及其成核机制[D]. 北京:中国地质大学(北京). Wang Zhipeng. 2017. The forming environment of the carbonate concretions of Mesoproterozoic Gaoyuzhuang Formation III menber and it’snucleation mechanism[D]. Beijing: China University of Geo-sciences (Beijing). |
| [15] | 张云望. 2024. 鄂尔多斯盆地早侏罗世Toarcian期陆相红层的成因及其地质意义[D]. 成都:成都理工大学. Zhang Yunwang. 2024. Continental red beds in the Ordos Basin: Origins and paleoclimatic implications following the Toarcian Oceanic Anoxic Event (Early Jurassic)[D]. Chengdu: Chengdu University of Techno-logy. |
| [16] | 张云望,金鑫,乔培军,等. 2023. 鄂尔多斯盆地东北部下侏罗统富县组沉积物源分析:来自榆林安崖剖面砂岩的岩石学及元素地球化学证据[J]. 沉积学报,41(5):1414-1429. Zhang Yunwang, Jin Xin, Qiao Peijun, et al. 2023. Petrological and geochemical constraints on sedimentary provenance of the Fuxian Formation (Lower Jurassic) sandstones in the northeastern Ordos Basin[J]. Acta Sedimentologica Sinica, 41(5): 1414-1429. |
| [17] | 张之辉. 2020. 鄂尔多斯盆地东北缘早—中侏罗世延安组成煤期古环境与古气候[D]. 北京:中国地质大学(北京). Zhang Zhihui. 2020. Paleoenvironment and paleoclimate of Early-Middle Jurassic Yan'an Formation coal-forming period in the northeast margin Ordos Basin[D]. Beijing: China University of Geosciences (Beijing). |
| [18] | 赵俊兴,陈洪德,张锦泉. 1999. 鄂尔多斯盆地下侏罗统富县组沉积体系及古地理[J]. 岩相古地理,19(5):40-46. Zhao Junxing, Chen Hongde, Zhang Jinquan. 1999. The depositional systems and palaeogeography of the Lower Jurassic Fuxian Formation in the Ordos Basin[J]. Sedimentary Facies and Palaeogeography, 19(5): 40-46. |
| [19] | 赵彦彦,李三忠,李达,等. 2019. 碳酸盐(岩)的稀土元素特征及其古环境指示意义[J]. 大地构造与成矿学,43(1):141-167. Zhao Yanyan, Li Sanzhong, Li Da, et al. 2019. Rare earth element geochemistry of carbonate and its paleoenvironmental implications[J]. Geotectonica et Metallogenia, 43(1): 141-167. |
| [20] | 周传明,张俊明,李国祥,等. 1997. 云南永善肖滩早寒武世早期碳氧同位素记录[J]. 地质科学,32(2):201-211. Zhou Chuanming, Zhang Junming, Li Guoxiang, et al. 1997. Cabbon and oxygen isotopic record of the early Cambrian from the Xiaotan section, Yunnan, South China[J]. Scientia Geologica Sinica, 32(2): 201-211. |
| [21] | 朱祥坤,张衔,张飞飞,等. 2013. 蓟县中元古界下马岭组中菱铁矿的发现及其意义[J]. 地质论评,59(5):816-822. Zhu Xiangkun, Zhang Xian, Zhang Feifei, et al. 2013. Discovery of siderite concretes in Mesoproterozoic Xiamaling Formation, Jixian section[J]. Geological Review, 59(5): 816-822. |
| [22] | Ábalos B, Elorza J. 2012. Structural diagenesis of siderite layers in black shales (Albian Black Flysch, northern Spain)[J]. The Journal of Geology, 120(4): 405-429. |
| [23] | Aharon P. 2005. Redox stratification and anoxia of the Early Precam-brian oceans: Implications for carbon isotope excursions and oxidation events[J]. Precambrian Research, 137(3/4): 207-222. |
| [24] | Aharon P, Liew T C. 1992. An assessment of the Precambrian/Cambrian transition events on the basis of carbon isotope records[M]//Schidlowski M, Golubic S, Kimberley M M, et al. Early organic evolution: Implications for mineral and energy resources. Berlin, Heidelberg: Springer: 212-223. |
| [25] | Baranyi V, Jin X, Corso J D, et al. 2024. Vegetation response to climate change during an Early Jurassic Hyperthermal Event (Jenkyns Event) from northern China (Ordos Basin)[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 643: 112180. |
| [26] | Baranyi V, Jin X, dal Corso J, et al. 2023. Collapse of terrestrial ecosystems linked to heavy metal poisoning during the Toarcian oceanic anoxic event[J]. Geology, 51(7): 652-656. |
| [27] | Bekker A, Karhu J A, Eriksson K A, et al. 2003. Chemostratigraphy of Paleoproterozoic carbonate successions of the Wyoming Craton: Tectonic forcing of biogeochemical change?[J]. Precambrian Research, 120(3/4): 279-325. |
| [28] | Bekker A, Kaufman A J, Karhu J A, et al. 2001. Chemostratigraphy of the Paleoproterozoic Duitschland Formation, South Africa: Implications for coupled climate change and carbon cycling[J]. American Journal of Science, 301(3): 261-285. |
| [29] | Bekker A, Slack J F, Planavsky N, et al. 2010. Iron formation: The sedimentary product of a complex interplay among mantle, tectonic, oceanic, and biospheric processes[J]. Economic Geology, 105(3): 467-508. |
| [30] | Berner R A. 1981. A new geochemical classification of sedimentary environments[J]. Journal of Sedimentary Research, 51(2): 359-365. |
| [31] | Beukes N J, Gutzmer J. 2008. Origin and paleoenvironmental significance of major iron formations at the Archean-Paleoproterozoic boundary[J]. Reviews in Economic Geology, 15: 5-47. |
| [32] | Canfield D E, Raiswell R, Bottrell S H. 1992. The reactivity of sedimentary iron minerals toward sulfide[J]. American Journal of Science, 292(9): 659-683. |
| [33] | Criss R, Cooke G, Day S D. 1988. An organic origin for the carbonate concretions of the Ohio Shale[R]. U.S. Geological Survey Bulletin. |
| [34] | Emerson S R, Huested S S. 1991. Ocean anoxia and the concentrations of molybdenum and vanadium in seawater[J]. Marine Chemistry, 34(3/4): 177-196. |
| [35] | Flügel E. 2010. Microfacies of carbonate rocks: Analysis, interpretation and application[M]. Berlin, Heidelberg: Springer: 976. |
| [36] | Gäb F, Ballhaus C, Siemens J, et al. 2017. Siderite cannot be used as CO2 sensor for archaean atmospheres[J]. Geochimica et Cosmochimica Acta, 214: 209-225. |
| [37] | Gaines R R, Vorhies J S. 2016. Growth mechanisms and geochemistry of carbonate concretions from the Cambrian Wheeler Formation (Utah, USA)[J]. Sedimentology, 63(3): 662-698. |
| [38] | Garcia T I, Gorton M P, Li H, et al. 2016. The geochemistry of the 2.7 5 Ga-old Helen iron formation, Wawa, ontario-insights into Iron formation deposition from carbon isotopes and rare earth elements[J]. Precambrian Research, 275: 357-368. |
| [39] | Gurvich E G. 2006. Metalliferous sediments of the world ocean: Fundamental theory of deep-sea hydrothermal sedimentation[M]. Berlin, Heidelberg: Springer: 416. |
| [40] | Halama M, Swanner E D, Konhauser K O, et al. 2016. Evaluation of siderite and magnetite formation in BIFs by pressure–temperature experiments of Fe(III) minerals and microbial biomass[J]. Earth and Planetary Science Letters, 450: 243-253. |
| [41] | Haley B A, Klinkhammer G P, McManus J. 2004. Rare earth elements in pore waters of marine sediments[J]. Geochimica et Cosmochimica Acta, 68(6): 1265-1279. |
| [42] | Heimann A, Johnson C M, Beard B L, et al. 2010. Fe, C, and O isotope compositions of banded iron formation carbonates demonstrate a major role for dissimilatory iron reduction in ~2.5 Ga marine environments[J]. Earth and Planetary Science Letters, 294(1/2): 8-18. |
| [43] | Hesselbo S P, Gröcke D R, Jenkyns H C, et al. 2000. Massive dissociation of gas hydrate during a Jurassic oceanic anoxic event[J]. Nature, 406(6794): 392-395. |
| [44] | Hu X M, Li J, Han Z, et al. 2020. Two types of hyperthermal events in the Mesozoic-Cenozoic: Environmental impacts, biotic effects, and driving mechanisms[J]. Science China Earth Sciences, 63(8): 1041-1058. |
| [45] | Huang Y Z, Jin X, Pancost R D, et al. 2024. An intensified lacustrine methane cycle during the Toarcian OAE (Jenkyns Event) in the Ordos Basin, northern China[J]. Earth and Planetary Science Letters, 639: 118766. |
| [46] | Irwin H, Curtis C, Coleman M. 1977. Isotopic evidence for source of diagenetic carbonates formed during burial of organic-rich sediments[J]. Nature, 269(5625): 209-213. |
| [47] | James H L. 1954. Sedimentary facies of iron-formation[J]. Economic Geology, 49(3): 235-293. |
| [48] | Jenkyns H C. 1985. The Early Toarcian and Cenomanian-Turonian anoxic events in Europe: Comparisons and contrasts[J]. Geologische Rundschau, 74(3): 505-518. |
| [49] | Jenkyns H C. 1988. The Early Toarcian (Jurassic) anoxic event; stratigraphic, sedimentary and geochemical evidence[J]. American Journal of Science, 288(2): 101-151. |
| [50] | Jenkyns H C. 2010. Geochemistry of oceanic anoxic events[J]. Geochemistry, Geophysics, Geosystems, 11(3): 30. |
| [51] | Jin X, Shi Z Q, Baranyi V, et al. 2020. The Jenkyns event (Early Toarcian OAE) in the Ordos Basin, North China[J]. Global and Planetary Change, 193: 103273. |
| [52] | Jin X, Zhang F, Baranyi V, et al. 2022. Early Jurassic massive release of terrestrial mercury linked to floral crisis[J]. Earth and Planetary Science Letters, 598: 117842. |
| [53] | Johnson C M, Beard B L, Klein C, et al. 2008. Iron isotopes constrain biologic and abiologic processes in banded iron formation genesis[J]. Geochimica et Cosmochimica Acta, 72(1): 151-169. |
| [54] | Kaufman A J, Knoll A H. 1995. Neoproterozoic variations in the C-isotopic composition of seawater: Stratigraphic and biogeochemical implications[J]. Precambrian Research, 73: 27-49. |
| [55] | Klein C. 2005. Some Precambrian banded iron-formations (BIFs) from around the world: Their age, geologic setting, mineralogy, metamorphism, geochemistry, and origins[J]. American Mineralogist, 90(10): 1473-1499. |
| [56] | Knauth L P, Kennedy M J. 2009. The Late Precambrian greening of the earth[J]. Nature, 460(7256): 728-732. |
| [57] | Konhauser K O, Newman D K, Kappler A. 2005. The potential significance of microbial Fe(III) reduction during deposition of Precambrian banded iron formations[J]. Geobiology, 3(3): 167-177. |
| [58] | Krylov A, Khlystov O, Zemskaya T, et al. 2008. First discovery and formation process of authigenic siderite from gas hydrate–bearing mud volcanoes in fresh water: Lake Baikal, eastern Siberia[J]. Geophysical Research Letters, 35(5): L05405. |
| [59] | Lewan M D. 1984. Factors controlling the proportionality of vanadium to nickel in crude oils[J]. Geochimica et Cosmochimica Acta, 48(11): 2231-2238. |
| [60] | Li B B, Jin X, Corso J D, et al. 2023. Complex pattern of environmental changes and organic matter preservation in the NE Ordos lacustrine depositional system (China) during the T-OAE (Early Jurassic)[J]. Global and Planetary Change, 221: 104045. |
| [61] | Li W Q, Beard B L, Johnson C M. 2015. Biologically recycled continental iron is a major component in banded iron formations[J]. Proceedings of the National Academy of Sciences of the United States of America, 112(27): 8193-8198. |
| [62] | Liu M, Sun P, Them II T R, et al. 2020. Organic geochemistry of a lacustrine shale across the Toarcian Oceanic Anoxic Event (Early Jurassic) from NE China[J]. Global and Planetary Change, 191: 103214. |
| [63] | Liu X T, Fike D, Li A C, et al. 2019. Pyrite sulfur isotopes constrained by sedimentation rates: Evidence from sediments on the East China Sea inner shelf since the Late Pleistocene[J]. Chemical Geology, 505: 66-75. |
| [64] | Lovley D R. 1991. Dissimilatory Fe(III) and Mn(IV) reduction[J]. Microbiological reviews, 55(2): 259-287. |
| [65] | Matsumoto R. 1989. Isotopically heavy oxygen-containing siderite derived from the decomposition of methane hydrate[J]. Geology, 17(8): 707-710. |
| [66] | Meng F, Han Z, Hu X M, et al. 2024. Siderite from the Tibetan Himalaya: Evidence for a low sulphate ocean during Oceanic Anoxic Event 1a (Early Aptian)[J]. Sedimentology, 71(7): 2358-2377. |
| [67] | Morford J L, Russell A D, Emerson S. 2001. Trace metal evidence for changes in the redox environment associated with the transition from terrigenous clay to diatomaceous sediment, Saanich Inlet, BC[J]. Marine Geology, 174(1/4): 355-369. |
| [68] | Mozley P S. 1989. Relation between depositional environment and the elemental composition of early diagenetic siderite[J]. Geology, 17(8): 704-706. |
| [69] | Mozley P S, Wersin P. 1992. Isotopic composition of siderite as an indicator of depositional environment[J]. Geology, 20(9): 817-820. |
| [70] | Ohmoto H, Watanabe Y, Kumazawa K. 2004. Evidence from massive siderite beds for a CO2-rich atmosphere before ~1.8 billion years ago[J]. Nature, 429(6990): 395-399. |
| [71] | Pálfy J, Smith P L. 2000. Synchrony between Early Jurassic extinction, oceanic anoxic event, and the Karoo-Ferrar flood basalt volcanism[J]. Geology, 28(8): 747-750. |
| [72] | Peckmann J, Thiel V. 2004. Carbon cycling at ancient methane-seeps[J]. Chemical Geology, 205(3/4): 443-467. |
| [73] | Pieńkowski G, Hodbod M, Ullmann C V. 2016. Fungal decomposition of terrestrial organic matter accelerated Early Jurassic climate warming[J]. Scientific Reports, 6(1): 31930. |
| [74] | Piper D Z, Calvert S E. 2009. A marine biogeochemical perspective on black shale deposition[J]. Earth-Science Reviews, 95(1/2): 63-96. |
| [75] | Planavsky N, Bekker A, Rouxel O J, et al. 2010. Rare earth element and yttrium compositions of Archean and Paleoproterozoic Fe formations revisited: New perspectives on the significance and mechanisms of deposition[J]. Geochimica et Cosmochimica Acta, 74(22): 6387-6405. |
| [76] | Plet C, Grice K, Pagès A, et al. 2016. Microbially-mediated fossil-bearing carbonate concretions and their significance for palaeoenvironmental reconstructions: A multi-proxy organic and inorganic geochemical appraisal[J]. Chemical Geology, 426: 95-108. |
| [77] | Posth N R, Konhauser K O, Kappler A. 2013. Microbiological processes in banded iron formation deposition[J]. Sedimentology, 60(7): 1733-1754. |
| [78] | Pye K, Dickson J A D, Schiavon N, et al. 1990. Formation of siderite-Mg-calcite-iron sulphide concretions in intertidal marsh and sandflat sediments, North Norfolk, England[J]. Sedimentology, 37(2): 325-343. |
| [79] | Raiswell R. 1987. Non-steady state microbiological diagenesis and the origin of concretions and nodular limestones[J]. Geological Society, London, Special Publications, 36(1): 41-54. |
| [80] | Rasmussen B, Meier D B, Krapež B, et al. 2013. Iron silicate microgranules as precursor sediments to 2.5-billion-year-old banded iron formations[J]. Geology, 41(4): 435-438. |
| [81] | Romanek C S, Jiméenez-López C, Navarro A R, et al. 2009. Inorganic synthesis of Fe-Ca-Mg carbonates at low temperature[J]. Geo-chimica et Cosmochimica Acta, 73(18): 5361-5376. |
| [82] | Surya P L, Ray D, Paropkari A L, et al. 2012. Distribution of REEs and yttrium among major geochemical phases of marine Fe-Mn-oxides: Comparative study between hydrogenous and hydrothermal deposits[J]. Chemical Geology, 312/313: 127-137. |
| [83] | Teixeira N L, Caxito F A, Rosière C A, et al. 2017. Trace elements and isotope geochemistry (C, O, Fe, Cr) of the Cauê iron formation, Quadrilátero Ferrífero, Brazil: Evidence for widespread microbial dissimilatory iron reduction at the Archean/Paleoproterozoic Transition[J]. Precambrian Research, 298: 39-55. |
| [84] | Them T R, Gill B C, Caruthers A H, et al. 2018. Thallium isotopes reveal protracted anoxia during the Toarcian (Early Jurassic) associated with volcanism, carbon burial, and mass extinction[J]. Proceedings of the National Academy of Sciences of the United States of America, 115(26): 6596-6601. |
| [85] | Tice M M, Lowe D R. 2004. Photosynthetic microbial mats in the 3,416-Myr-old ocean[J]. Nature, 431(7008): 549-552. |
| [86] | van der Weijden C H. 1992. Early diagenesis and marine pore water[J]. Developments in Sedimentology, 47: 13-134. |
| [87] | Wu Q W, Jin X, Karádi V, et al. 2024. Norian (Upper Triassic) carbon isotopic perturbations and conodont biostratigraphy from the Simao terrane, eastern Tethys[J]. Palaeogeography, Palaeoclimatology, Palaeoecology, 650: 112380. |
| [88] | Xu W M, Ruhl M, Jenkyns H C, et al. 2017. Carbon sequestration in an expanded lake system during the Toarcian oceanic anoxic event[J]. Nature Geoscience, 10(2): 129-134. |
| [89] | Xu W M, Ruhl M, Jenkyns H C, et al. 2018. Evolution of the Toarcian (Early Jurassic) carbon-cycle and global climatic controls on local sedimentary processes (Cardigan Bay Basin, UK)[J]. Earth and Planetary Science Letters, 484: 396-411. |
| [90] | Zhang S C, Wang X M, Wang H J, et al. 2016. Sufficient oxygen for animal respiration 1,400 million years ago[J]. Proceedings of the National Academy of Sciences of the United States of America, 113(7): 1731-1736. |