{"title":"Lateral redox variability in ca. 1.9 Ga marine environments indicated by organic carbon and nitrogen isotope compositions","authors":"Kento Motomura, Andrey Bekker, Minoru Ikehara, Takashi Sano, Ying Lin, Shoichi Kiyokawa","doi":"10.1111/gbi.12614","DOIUrl":null,"url":null,"abstract":"<p>The stepwise oxygenation of Earth's surficial environment is thought to have shaped the evolutionary history of life. Microfossil records and molecular clocks suggest eukaryotes appeared during the Paleoproterozoic, perhaps shortly after the Great Oxidation Episode at ca. 2.43 Ga. The mildly oxygenated atmosphere and surface oceans likely contributed to the early evolution of eukaryotes. However, the principal trigger for the eukaryote appearance and a potential factor for their delayed expansion (i.e., intermediate ocean redox conditions until the Neoproterozoic) remain poorly understood, largely owing to a lack of constraints on marine and terrestrial nutrient cycling. Here, we analyzed redox-sensitive element contents and organic carbon and nitrogen isotope compositions of relatively low metamorphic-grade (greenschist facies) black shales preserved in the Flin Flon Belt of central Canada to examine open-marine redox conditions and biological activity around the ca. 1.9 Ga Flin Flon oceanic island arc. The black shale samples were collected from the Reed Lake area in the eastern part of the Flin Flon Belt, and the depositional site was likely distal from the Archean cratons. The black shales have low Al/Ti ratios and are slightly depleted in light rare-earth elements relative to the post-Archean average shale, which is consistent with a limited contribution from felsic igneous rocks in Archean upper continental crust. Redox conditions have likely varied between suboxic and euxinic at the depositional site of the studied section, as suggested by variable U/Al and Mo/Al ratios. Organic carbon and nitrogen isotope compositions of the black shales are approximately −23‰ and +13.7‰, respectively, and these values are systematically higher than those of broadly coeval continental margin deposits (approximately −30‰ for δ<sup>13</sup>C<sub>org</sub> and +5‰ for δ<sup>15</sup>N<sub>bulk</sub>). These elevated values are indicative of high productivity that led to enhanced denitrification (i.e., a high denitrification rate relative to nitrogen influx at the depositional site). Similar geochemical patterns have also been observed in the modern Peruvian oxygen minimum zone where dissolved nitrogen compounds are actively lost from the reservoir via denitrification and anammox, but the large nitrate reservoir of the deep ocean prevents exhaustion of the surface nitrate pool. Nitrogen must have been widely bioavailable in the ca. 1.9 Ga oceans, and its supply to upwelling zones must have supported habitable environments for eukaryotes, even in the middle of oceans around island arcs.</p>","PeriodicalId":173,"journal":{"name":"Geobiology","volume":"22 4","pages":""},"PeriodicalIF":2.7000,"publicationDate":"2024-08-11","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Geobiology","FirstCategoryId":"89","ListUrlMain":"https://onlinelibrary.wiley.com/doi/10.1111/gbi.12614","RegionNum":2,"RegionCategory":"地球科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"BIOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
The stepwise oxygenation of Earth's surficial environment is thought to have shaped the evolutionary history of life. Microfossil records and molecular clocks suggest eukaryotes appeared during the Paleoproterozoic, perhaps shortly after the Great Oxidation Episode at ca. 2.43 Ga. The mildly oxygenated atmosphere and surface oceans likely contributed to the early evolution of eukaryotes. However, the principal trigger for the eukaryote appearance and a potential factor for their delayed expansion (i.e., intermediate ocean redox conditions until the Neoproterozoic) remain poorly understood, largely owing to a lack of constraints on marine and terrestrial nutrient cycling. Here, we analyzed redox-sensitive element contents and organic carbon and nitrogen isotope compositions of relatively low metamorphic-grade (greenschist facies) black shales preserved in the Flin Flon Belt of central Canada to examine open-marine redox conditions and biological activity around the ca. 1.9 Ga Flin Flon oceanic island arc. The black shale samples were collected from the Reed Lake area in the eastern part of the Flin Flon Belt, and the depositional site was likely distal from the Archean cratons. The black shales have low Al/Ti ratios and are slightly depleted in light rare-earth elements relative to the post-Archean average shale, which is consistent with a limited contribution from felsic igneous rocks in Archean upper continental crust. Redox conditions have likely varied between suboxic and euxinic at the depositional site of the studied section, as suggested by variable U/Al and Mo/Al ratios. Organic carbon and nitrogen isotope compositions of the black shales are approximately −23‰ and +13.7‰, respectively, and these values are systematically higher than those of broadly coeval continental margin deposits (approximately −30‰ for δ13Corg and +5‰ for δ15Nbulk). These elevated values are indicative of high productivity that led to enhanced denitrification (i.e., a high denitrification rate relative to nitrogen influx at the depositional site). Similar geochemical patterns have also been observed in the modern Peruvian oxygen minimum zone where dissolved nitrogen compounds are actively lost from the reservoir via denitrification and anammox, but the large nitrate reservoir of the deep ocean prevents exhaustion of the surface nitrate pool. Nitrogen must have been widely bioavailable in the ca. 1.9 Ga oceans, and its supply to upwelling zones must have supported habitable environments for eukaryotes, even in the middle of oceans around island arcs.
地球表面环境的逐步富氧被认为塑造了生命的进化史。微化石记录和分子钟显示,真核生物出现在古近纪,也许是在约 2.43 Ga 的大氧化作用之后不久。轻度含氧的大气和表层海洋很可能促进了真核生物的早期进化。然而,人们对真核生物出现的主要诱因及其延迟扩展的潜在因素(即直到新近纪的中间海洋氧化还原条件)仍然知之甚少,这主要是由于缺乏对海洋和陆地营养循环的制约。在这里,我们分析了加拿大中部弗林弗隆带保存的变质程度相对较低(绿泥石面)的黑色页岩的氧化还原敏感元素含量以及有机碳和氮同位素组成,以研究约 1.9 Ga 弗林弗隆带附近的开放海洋氧化还原条件和生物活动。1.9 Ga 的弗林弗隆洋岛弧周围的开放海洋氧化还原条件和生物活动。黑色页岩样本采集自弗林弗隆带东部的里德湖地区,沉积地点很可能远离阿基坦陨石坑。黑色页岩的铝/钛比值较低,轻稀土元素含量也略低于后阿基坦平均页岩,这与阿基坦上部大陆地壳中长石火成岩的贡献有限相一致。研究区段沉积地点的氧化还原条件很可能在亚氧化和氧化还原之间变化,U/Al 和 Mo/Al 比率的变化表明了这一点。黑色页岩的有机碳和氮同位素组成分别约为-23‰和+13.7‰,这些数值系统地高于大致同时期的大陆边缘沉积物(δ13Corg约为-30‰,δ15Nbulk约为+5‰)。这些升高的数值表明,高生产力导致反硝化作用增强(即相对于沉积地点的氮流入量,反硝化率较高)。在现代秘鲁最小含氧区也观察到了类似的地球化学模式,那里的溶解氮化合物通过反硝化作用和anammox作用从储层中积极地流失,但深海的大型硝酸盐储层阻止了地表硝酸盐池的耗竭。在大约 1.9 Ga 的海洋中,氮一定具有广泛的生物可利用性。即使在岛弧周围的海洋中间,氮也一定为真核生物提供了适宜居住的环境。
期刊介绍:
The field of geobiology explores the relationship between life and the Earth''s physical and chemical environment. Geobiology, launched in 2003, aims to provide a natural home for geobiological research, allowing the cross-fertilization of critical ideas, and promoting cooperation and advancement in this emerging field. We also aim to provide you with a forum for the rapid publication of your results in an international journal of high standing. We are particularly interested in papers crossing disciplines and containing both geological and biological elements, emphasizing the co-evolutionary interactions between life and its physical environment over geological time.
Geobiology invites submission of high-quality articles in the following areas:
Origins and evolution of life
Co-evolution of the atmosphere, hydrosphere and biosphere
The sedimentary rock record and geobiology of critical intervals
Paleobiology and evolutionary ecology
Biogeochemistry and global elemental cycles
Microbe-mineral interactions
Biomarkers
Molecular ecology and phylogenetics.
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