A highly redox-heterogeneous ocean in South China during the early Cambrian (∼529–514 Ma): Implications for biota-environment co-evolution

Jin, Chengsheng; Li, Chao; Algeo, Thomas J.; Planavsky, Noah J.; Cui, Hao; Yang, Xing; Zhao, Yuanlong; Zhang, Xingliang; Xie, Shucheng

doi:10.1016/j.epsl.2016.02.019

Cited by 207 publications

(135 citation statements)

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“…This implies that earlier positive δ 98 Mo excursions (~2 ‰) in Terreneuvian phosphorite deposits (Wen et al, 2011), and perhaps in the latest Ediacaran (Kendall et al, 2015), represent episodic events rather than persistent ocean oxygenation. Similarly, detailed studies of the bottom water redox conditions in the Nanhua Basin, South China, suggest that oxygenated waters also invaded shallower part of the basin later in the Stage 3 (Jin et al 2016). As such, the oxygenation history of the early Cambrian ocean appears more dynamic than previously thought (e.g., Dahl et al, 2010;Sperling et al, 2013;Chen et al, 2015).…”

mentioning

confidence: 76%

“…Specifically, the molybdenum isotope (δ 98 Mo) record from shales and phosphorites show several fluctuations recorded in ~560 to 520 Myr old stratigraphic sections in China (Wille et al, 2008;Wen et al, 2011;Xu et al, 2012;Chen et al, 2015;Kendall et al, 2015;Wen et al, 2015). The last positive δ 98 Mo excursion is broadly correlated to the first appearance of trilobites in China, strong Mo enrichments and with the oxygenation event reported here (Dahl et al, 2010;Xu et al, 2012;Chen et al, 2015;Wen et al, 2015;Jin et al, 2016). The coincident positive δ 98 Mo and δ 238 U excursions point to a widespread oxygenation episode in the earliest Cambrian Stage 3 oceans where O 2 -rich waters expanded and affected the Mo and U isotope composition of seawater as the overall burial fluxes of Mo and U into anoxic and euxinic settings decreased.…”

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confidence: 89%

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Reorganisation of Earth’s biogeochemical cycles brieﬂy oxygenated the oceans 520 Myr ago

Dahl

Connelly

Kouchinsky³

et al. 2017

Geochem. Persp. Let.

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The Phanerozoic radiation of bilaterian animals has been linked to oxygenation of Earth's oceans, due to the oxygen demand of the evolving animal ecosystems. However, how early animals may have regulated Earth's surface oxygen budget via self-stabilising feedbacks is poorly understood. Here, we report parallel positive uranium, carbon, and sulphur isotope excursions from carbonate successions in Siberia that document a brief global oxygenation episode 521-520 Myr ago, at the onset of diversification of larger arthropods known from the fossil record. Our data and model indicate that an abrupt increase in the sinking rate of marine organic matter expanded the oxygenated zone in the oceans and that reducing conditions returned 1.3 ± 0.8 Myr after the onset of this transient oxygenation episode, necessitating a strong negative feedback to the increasing levels of oxygen. We speculate that larger zooplankton could have sourced both oxygen and food to the seafloor, fueling bioturbation over wider areas and, thereby, stabilising O 2 -rich habitats in the oceans. Thus, this reorganisation exemplifies how animal ecosystems might have influenced oxygen availability in Earth's surface environment soon after their establishment. LetterIn contrast to many geochemical proxies that evaluate local ancient marine redox including iron speciation and trace metal (Mo, U, V) enrichments, the uranium isotope composition (δ 238 U, the per mille deviation of the 238 U/ 235 U ratio relative to CRM 145 standard) of seawater can be used to evaluate ocean oxygenation at 1. Natural History Museum of Denmark, University of Copenhagen, Denmark * Corresponding author (email: tais.dahl@snm.ku.dk) 2. Centre for Star and Planet Formation, University of Copenhagen, Denmark 3. Swedish Museum of Natural History, Stockholm, Sweden 4. Virginia Polytechnic Institute and State University, Blacksburg, USA a globally integrated scale. This is possible due to the long residence time and uniform δ 238 U of uranium in the modern ocean and predicted for the Cambrian ocean (Weyer et al., 2008;Dahl et al., 2014;Tissot and Dauphas, 2015). The δ 238 U proxy has been utilised to track past global ocean redox during three known oceanic anoxic events (Montoya-Pino et al., 2010;Brennecka et al., 2011;Dahl et al., 2014;Elrick et al., 2016;Lau et al., 2016), where anoxic water masses expanded over larger areas of the seafloor and caused negative δ 238 U excursions. Here, we use uranium isotopes to identify a transient global oxygenation episode during the radiation of animals in the Cambrian.Our new δ 238 U data of carbonate-associated uranium comes from limestones collected from the Siberian Platform across the provisional Cambrian Stage 2-3 boundary (~521 to 520 million years ago) (Fig. 1), when animals that shed their exoskeleton (ecdysozoa) began to diversify (Maloof et al., 2010;Kouchinsky et al., 2012). A perturbation in the marine carbon cycle is expressed at this time as a large positive carbon isotope excursion recognised globally and in all studied sections;...

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confidence: 76%

mentioning

confidence: 89%

Reorganisation of Earth’s biogeochemical cycles brieﬂy oxygenated the oceans 520 Myr ago

Dahl

Connelly

Kouchinsky³

et al. 2017

Geochem. Persp. Let.

View full text Add to dashboard Cite

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“…This oceanic structure likely did not change in nature until the Cambrian Age 3 (ca. 520 Ma) (Jin et al, 2016).…”

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confidence: 96%

“…However, recent studies have yielded evidence of a highly redoxstratified structure for the early-Earth oceans (>520Ma), in which a mid-depth euxinic water mass was maintained dynamically on continental shelves between oxic proximal-shelf waters and ferruginous deep-ocean waters (i.e., the "euxinic wedge" model; Fig. 1d; Jin et al, 2016;Guilbaud et al, 2015;Poulton and Canfield, 2011;Li et al, 2010;Poulton et al, 2010). Notably, this highly redox-stratified structure of ocean chemistry has been proposed to help the buildup of a large dissolved organic carbon reservoir in the Ediacaran deep oceans (Wang et al, 2015;Li et al, 2010).…”

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confidence: 98%

Preface: Atmospheric and oceanic oxygenation and evolution of early life on Earth: New contributions from China

Zhu

Chu

2016

J. Earth Sci.

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“…Most current models linking early animal evolution to redox chemistry assume a horizontally stratified ocean (Wood et al, 2015;Jin et al, 2016). However, modern oceans exhibit a marked lateral redox variability, most notably where combinations of high primary productivity and metazoan activity (Bianchi et al, 2013) give rise to wedge-shaped oxygen minimum zones (Sperling et al, 2015a).…”

Section: Introductionmentioning

confidence: 99%

Oxygen minimum zones in the early Cambrian ocean

Guilbaud¹,

Slater²,

Poulton³

et al. 2018

Geochem. Persp. Let.

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The relationship between the evolution of early animal communities and oceanic oxygen levels remains unclear. In particular, uncertainty persists in reconstructions of redox conditions during the pivotal early Cambrian (541-510 million years ago, Ma), where conflicting datasets from deeper marine settings suggest either ocean anoxia or fully oxygenated conditions. By coupling geochemical palaeoredox proxies with a record of organic-walled fossils from exceptionally well-defined successions of the early Cambrian Baltic Basin, we provide evidence for the early establishment of modern-type oxygen minimum zones (OMZs). Both innerand outer-shelf environments were pervasively oxygenated, whereas mid-depth settings were characterised by spatially oscillating anoxia. As such, conflicting redox signatures recovered from individual sites most likely derive from sampling bias, whereby anoxic conditions represent mid-shelf environments with higher productivity. This picture of a spatially restricted anoxic wedge contrasts with prevailing models of globally stratified oceans, offering a more nuanced and realistic account of the Proterozoic-Phanerozoic ocean transition.

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A highly redox-heterogeneous ocean in South China during the early Cambrian (∼529–514 Ma): Implications for biota-environment co-evolution

Cited by 207 publications

References 70 publications

Reorganisation of Earth’s biogeochemical cycles brieﬂy oxygenated the oceans 520 Myr ago

Reorganisation of Earth’s biogeochemical cycles brieﬂy oxygenated the oceans 520 Myr ago

Preface: Atmospheric and oceanic oxygenation and evolution of early life on Earth: New contributions from China

Oxygen minimum zones in the early Cambrian ocean

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