Collaborative Research: Tracking Middle-late Paleozoic Global-ocean Redox Conditions Using U Isotopes in Marine Carbonates

合作研究：利用海洋碳酸盐中的U同位素追踪中晚古生代全球海洋氧化还原条件

• 批准号: 1733598
• 负责人: Stephen Romaniello
• 金额: $ 14.11万
• 依托单位: Arizona State University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2017
• 资助国家: 美国
• 起止时间: 2017-09-01 至 2020-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1733598&HistoricalAwards=false
• 关键词: Collaborative; Research; Tracking; Middle; late

The goal of the funded proposal is to determine the relative amounts of oxygen dissolved in ancient oceans during a unique geologic time interval (300 to 420 million years ago) when three major mass extinctions occurred and the Earth was significantly warmer than today. Understanding the history of oxygen levels in ancient oceans is important because oxygen concentrations influence all marine animal life, control the formation and preservation of petroleum and many economic mineral deposits, and affect important biochemical reactions in the oceans and atmosphere. This project utilizes the relatively new geochemical tool of uranium isotopes to develop the most detailed history of changing ocean oxygen concentrations to date. The funding supports the training of the next generation of Earth scientists, will provide hands-on field and laboratory experience for first-generation college students, and will support multiple primary school science teachers to conduct real-world science to gain confidence and provide new ideas for their own classrooms. The project goal is to develop a global-ocean redox curve using U isotopes from Devonian-Mississippian marine carbonates. The ~100 million year study interval, which bridges the transition between poorly oxygenated Precambrian-Early Paleozoic oceans and well-oxygenated Late Paleozoic-Recent oceans, is important because of: 1) a doubling of atmospheric pO2 levels, 2) a transition from greenhouse to icehouse climate and intensifying ocean circulation, 3) the occurrence of three mass extinctions, two of which are attributed to marine anoxia, and 4) multiple large positive 13C excursions. The U-isotope composition of marine carbonates has the potential to record mean global-ocean redox conditions owing to the long residence time (~500 thousand years) of U in seawater. Samples will be collected from biostratigraphically well-dated successions in Nevada and Utah at spacings ranging from ~100 thousand years/sample to 20 thousand years/sample through specific event intervals. To assess samples for local redox influences, we will analyze redox-sensitive metals, Fe-speciation, and Corg:P ratios. To verify the global nature of the composite curve, we will sample and compare to selected shorter stratigraphic intervals on other continents.

这项资助提案的目标是确定在一个独特的地质时间间隔（3亿至4.2亿年前）内溶解在古代海洋中的氧气的相对数量，当时发生了三次大规模的大规模灭绝，地球比今天温暖得多。了解古代海洋中氧含量的历史非常重要，因为氧浓度影响所有海洋动物的生命，控制石油和许多经济矿藏的形成和保存，并影响海洋和大气中的重要生物化学反应。该项目利用铀同位素这一相对较新的地球化学工具，研究迄今为止海洋氧浓度变化的最详细历史。这笔资金将用于培训下一代地球科学家，为第一代大学生提供实地和实验室实践经验，并将支持多名小学科学教师进行真实世界的科学，以获得信心并为自己的课堂提供新的想法。 该项目的目标是利用泥盆纪-密西西比纪海洋碳酸盐中的铀同位素绘制全球海洋氧化还原曲线。约1亿年的研究间隔，桥接了贫氧的前寒武纪-早古生代海洋和富氧的晚古生代-现代海洋之间的过渡，这一研究间隔很重要，因为：1）大气pO 2水平加倍，2）从温室气候转变为冰库气候，海洋环流加剧，3）发生三次大规模降水，其中两次归因于海洋缺氧，和4）多个大的正 13 C偏移。 由于铀在海水中的停留时间较长（约50万年），海洋碳酸盐的铀同位素组成有可能记录全球海洋平均氧化还原条件。 将从内华达州和犹他州的生物地层学上有明确日期的连续地层中采集样本，样本间隔为约10万年/样本至2万年/样本，通过特定事件间隔。为了评估样品的局部氧化还原影响，我们将分析氧化还原敏感的金属，铁形态，和Corg：P比率。为了验证复合曲线的全球性质，我们将取样并与其他大陆上选定的较短地层间隔进行比较。