Collaborative Research: Dynamics of carbon release and sequestration: Case studies of two early Eocene hyperthermals

合作研究：碳释放和封存的动力学：两次始新世早期高温的案例研究

基本信息

批准号：
0628719
负责人：
James Zachos
金额：
$ 41.95万
依托单位：
University of California-Santa Cruz
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2006
资助国家：
美国
起止时间：
2006-09-15 至 2011-02-28
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=0628719&HistoricalAwards=false
关键词：
Collaborative Research Dynamics carbon release

项目摘要

ABSTRACTIntellectual Merit: The ocean is the largest sink for anthropogenic CO2 and has absorbed nearly 130 PgC of the 380 PgC emitted to the atmosphere since the onset of the Industrial Revolution. If emissions continue to rise unabated for the next three centuries, an additional 4000 PgC or more will be input to the atmosphere and ocean. Published model simulations of the ocean/atmosphere response to the eventual complete utilization of fossil fuels indicate that atmospheric CO2 will rise to levels that Earth likely hasn't experienced for at least 40 million years, and the surface ocean may undergo acidification to the extent that corals and other calcifying organisms will be unable to precipitate their skeletons. Confidence in and refinement of these model simulations will benefit from application to, and comparison with, analogous events in Earth history. Approximately 55 million years ago (Mya), Earth experienced a similar episode of rapid and extreme transient warming, the Paleocene-Eocene Thermal Maximum (PETM), likely the product of massive carbon release. Intense study of the PETM over the last five years has led to a far clearer understanding of the consequences of this event on climate, biota, and biogeochemical cycles. One of the more prominent advances is the documentation of evidence for widespread ocean acidification and buffering, consistent with carbon cycle theory. A related advance was the discovery of second warming and ocean acidification event at ~53 Mya. This event, known as ELMO, was less extreme than the PETM in every sense, from the carbon cycle perturbation to the magnitude of warming. These global warming events, termed hyperthermals, provide a unique opportunity to gain insight into the long-term impacts of rapidly rising CO2 levels on modern climate, ocean carbonate chemistry, and biotas. They also provide an opportunity to identify potential non-linear feedbacks, and test climate and biogeochemical model sensitivity. To this end, an interdisciplinary group of scientists with expertise in carbon cycle dynamics, sediment geochemistry, paleoceanography and paleobiology has been assembled, and will embark on a 4-year project to address critical questions regarding two hyperthermals, and their implications for understanding of the carbon cycle including: 1) what were the mass, rate, and origin of carbon released during the hyperthermals? 2) what were the rates of sequestration and recovery and what biogeochemical feedbacks came into play? and 3) how did associated extreme changes in ocean carbonate chemistry affect planktonic calcifiers? The strategy will involve integration of the observational database with numerical models. The observational database will be used to constrain and test the carbon cycle models. This includes records of biogenic carbonate production, accumulation and preservation in 3-dimensions through the PETM and ELMO. This will also require substantial refinement of age models. With a highly resolved and multifaceted data set for input, three modeling approaches will be used, each involving specific opportunities and compromises in terms of the time scales and scope of processes that can be modeled. Earth system models (GENIE and CCSM) will provide boundary conditions for the process-oriented models. Process model simulations will be designed to investigate problems identified during data/model validation of the Earth system models and to develop hypotheses to be tested with model simulations.Broader Impacts: This highly interdisciplinary project will provide important insight into the short-term and long-term fate of anthropogenic CO2 on the global carbon cycle, climate, and biota. Such information is essential to providing scientific leaders and policy makers with a better sense of the consequences of unabated anthropogenic CO2 emissions for global climate, ocean carbon chemistry and marine food chains. Moreover, the project places significant emphasis on a number of closely integrated research and educational activities that will lead to the development and circulation of educational materials related to abrupt climate change and training in how to integrate them in curricula. In addition, we will take advantage of highly successful existing programs to provide opportunities for undergraduates from under-represented groups to participate in cutting-edge, relevant, carbon-cycle research.

摘要智力价值：海洋是人为二氧化碳的最大汇，自工业革命开始以来，海洋吸收了排放到大气中的 380 PgC 中的近 130 PgC。如果未来三个世纪排放量继续有增无减，则将有 4000 PgC 或更多的额外物质进入大气和海洋。已发表的海洋/大气对最终完全利用化石燃料的反应的模型模拟表明，大气中的二氧化碳将上升到地球至少 4000 万年以来从未经历过的水平，并且表层海洋可能会酸化到以下程度：珊瑚和其他钙化生物将无法沉淀其骨骼。对这些模型模拟的信心和完善将受益于地球历史上类似事件的应用和比较。大约 5500 万年前（Mya），地球经历了类似的快速而极端的短暂变暖，即古新世-始新世最热期（PETM），这可能是大量碳释放的产物。过去五年对 PETM 的深入研究使我们对这一事件对气候、生物群和生物地球化学循环的影响有了更清晰的认识。更突出的进展之一是记录了广泛的海洋酸化和缓冲的证据，这与碳循环理论相一致。一个相关的进展是在~53 Mya 发现了第二次变暖和海洋酸化事件。这一被称为 ELMO 的事件，从碳循环扰动到变暖程度，在各个方面都没有 PETM 那么极端。这些被称为高温的全球变暖事件提供了一个独特的机会，可以深入了解二氧化碳水平快速上升对现代气候、海洋碳酸盐化学和生物群的长期影响。它们还提供了识别潜在非线性反馈并测试气候和生物地球化学模型敏感性的机会。为此，一个由碳循环动力学、沉积物地球化学、古海洋学和古生物学专业知识的跨学科科学家小组组成，并将开展一个为期 4 年的项目，以解决有关两种高温气流及其对理解高温气流的影响的关键问题。碳循环包括：1）高温期间释放的碳的质量、速率和来源是多少？ 2）封存和回收率是多少以及哪些生物地球化学反馈发挥了作用？ 3）海洋碳酸盐化学的相关极端变化如何影响浮游钙化物？该战略将涉及观测数据库与数值模型的整合。观测数据库将用于约束和测试碳循环模型。这包括通过 PETM 和 ELMO 进行的生物碳酸盐生产、积累和保存的 3 维记录。这还需要对年龄模型进行大幅细化。通过高度解析和多方面的输入数据集，将使用三种建模方法，每种方法都涉及可建模过程的时间尺度和范围方面的特定机会和妥协。地球系统模型（GENIE 和 CCSM）将为面向过程的模型提供边界条件。过程模型模拟将旨在调查地球系统模型的数据/模型验证过程中发现的问题，并提出要通过模型模拟进行测试的假设。更广泛的影响：这个高度跨学科的项目将为短期和长期的问题提供重要的见解。人为二氧化碳对全球碳循环、气候和生物群的长期命运。这些信息对于让科学领导者和政策制定者更好地了解人为二氧化碳排放量有增无减对全球气候、海洋碳化学和海洋食物链的影响至关重要。此外，该项目非常重视一些紧密结合的研究和教育活动，这些活动将导致与气候突变有关的教材的开发和流通以及如何将其纳入课程的培训。此外，我们将利用非常成功的现有项目，为代表性不足群体的本科生提供参与前沿、相关碳循环研究的机会。