Joyce E. Neilson, Rosalia Barili, Alexander Brasier, Luiz F. De Ros, Sarah Ledingham
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引用次数: 3
摘要
晚寒武世阶梯阶正碳同位素偏移标志着海洋化学和三叶虫动物群发生重大变化的时期。在碳同位素漂移之前和漂移本身,Laurentia和Gondwana的全球证据表明,在浅海潮下环境中,原生文石胶结伴随着文石卵体的沉积。然而,这发生在一个被广泛认为具有“方解石海”特征的时期,当时的初级无机相(海洋胶结物和流体)通常被认为是方解石相。研究了纽芬兰中晚寒武统Port au Port群的化学地层学,包括早期海相胶结物。在这里,海洋胶结物中锶的浓度在碳同位素峰值偏移时增加(峰值偏移时达到5500 ppm),然后在峰后偏移时下降,这与原始胶结物为文石相一致。这种趋势伴随着残余的模塑孔隙,再次表明文石前体。原生无机矿物学在很大程度上受海水Mg/Ca比值的控制,但对晚寒武世海洋Mg/Ca比值的估计是可变的(0.8-2)。在这个水平上,水温和二氧化碳分压等其他因素已被证明会影响矿物学,温暖的海水和高水平的二氧化碳有利于文石。在三叶虫主要区系更替的同时,引起碳同位素偏移的暖水和缺氧可能为文石的降水创造了有利条件。
The Steptoean Positive Carbon Isotope Excursion (SPICE), inorganic aragonite precipitation and sea water chemistry: Insights from the Middle–Late Cambrian Port au Port Group, Newfoundland
The Late Cambrian Steptoean Positive Carbon Isotope Excursion marks a time of significant change in ocean chemistry and trilobite faunas. On the lead up to the carbon isotope excursion and at the excursion itself, there is global evidence from Laurentia and Gondwana of cementation by primary aragonite in shallow subtidal environments accompanied by deposition of aragonitic ooids. However, this occurred at a time widely considered to have been characterised by ‘calcite seas’ when the primary inorganic phases (marine cements and ooids) are normally presumed calcitic. This study has investigated the chemostratigraphy of the Middle–Late Cambrian Port au Port Group, Newfoundland, including the early marine cements. Here, the marine cements contain increasing concentrations of strontium towards the peak carbon isotope excursion (up to 5500 ppm at the peak excursion) before dropping off post-peak excursion, consistent with the original cements having been aragonitic. This trend is accompanied by relict oomouldic porosity, again suggesting an aragonitic precursor. Primary inorganic mineralogy is largely controlled by the Mg/Ca ratio of sea water but estimates of the Mg/Ca ratio of Late Cambrian oceans are variable (0.8–2). At this level, other factors such as water temperature and pCO2 have been shown to affect mineralogy with warm waters and high levels of CO2 favouring aragonite. It is possible that the warm waters and anoxia that caused the carbon isotope excursion created conditions favourable for the precipitation of aragonite at the same time as major trilobite faunal turnover.