Collaborative Research: Chemical and microbiological studies of water-soluble alkanes in the ocean

合作研究：海洋中水溶性烷烃的化学和微生物研究

• 批准号: 1756242
• 负责人: Christopher Reddy
• 金额: $ 22.11万
• 依托单位: Woods Hole Oceanographic Institution
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2018
• 资助国家: 美国
• 起止时间: 2018-03-01 至 2021-02-28
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1756242&HistoricalAwards=false
• 关键词: Collaborative; Research; Chemical; microbiological; studies

This research project addresses the fate of hydrocarbons that enter the ocean, using geological oil seeps as a natural scientific laboratory.  The key issues of intellectual merit that will be addressed focus on the development and application of methodology to determine how the chemical properties of hydrocarbon molecules dictate whether they will be trapped in the ocean's interior or find their way to the atmosphere.  The research will further follow the fate of these molecules in the ocean's interior, determining how the ocean's bacterial population responds, and the extent to which responding bacteria will degrade these molecules. The broader impacts of this research will include the training of undergraduate and graduate students in scientific research and at-sea oceanographic training, as well as the dissemination of findings to policy makers striving to understand the fate and effects of hydrocarbons in the ocean.  Hydrocarbons enter the ocean through a combination of natural seepage, anthropogenic discharge and biological production, with profound impacts on ocean biogeochemistry, ecology, and the atmosphere. This research project addresses the chemical and biological processes affecting water-soluble alkanes in the ocean, using natural seeps to study their fluxes, partitioning between ocean and atmosphere, and the bacterial response to their input.  The intellectual merit of this research pertains to the behavior of highly volatile hydrocarbons, a class that is abundant in petroleum reservoirs and many crude and refined products, but is poorly understood in the ocean.  Volatile hydrocarbons display distinct behaviors compared with traditional oil in that they will partition to seawater or the atmosphere depending on their molecular structure and the context by which they enter the ocean, a combination of characteristics unsuitable for traditional fate and transport models that govern our understanding of liquid oil. This research project addresses this gap in knowledge through a plan to study volatile, water-soluble hydrocarbons in the context of natural seepage, focusing on key questions about their transport and fate, and the ocean?s microbial response. Two key questions include:  1) What factors control the partitioning of water-soluble alkanes between water and the atmosphere at natural seeps, and how does this affect their availability to microbes?  2)  What genomic and metabolic factors enable the microbial response to the input of water-soluble alkanes and how does the microbial response vary with regional oceanographic and geologic factors such as proximity to and flux from natural seepage?  The hypotheses that result from these questions will be tested through a series of oceanographic and laboratory-based experiments designed around natural oil seeps in the Pacific and in the Gulf of Mexico. The results of these studies promise to inform our understanding of the transport, fate, and effects of water-soluble alkanes in the ocean.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

这项研究项目利用地质石油渗漏作为自然科学实验室，解决了进入海洋的碳氢化合物的命运。将解决的关键智力问题集中在开发和应用方法学，以确定碳氢分子的化学性质如何决定它们是被困在海洋内部还是找到进入大气的途径。该研究将进一步跟踪这些分子在海洋内部的命运，确定海洋中的细菌种群如何反应。以及响应细菌降解这些分子的程度。这项研究的更广泛影响将包括对本科生和研究生进行科学研究和海上海洋学培训，以及向努力了解海洋中碳氢化合物的命运和影响的政策制定者传播研究结果。这些碳氢化合物通过自然渗漏、人为排放和生物生产的组合进入海洋，对海洋生物地球化学、生态和大气产生深刻影响。这项研究项目研究了影响海洋中水溶性烷烃的化学和生物过程，利用自然渗漏来研究它们的通量，海洋和大气之间的分配，以及细菌对它们输入的反应。这项研究的智力价值与高挥发性碳氢化合物的行为有关，高挥发性碳氢化合物是一类丰富的石油储藏物和许多原油和精炼产品，但在海洋中知之甚少。与传统石油相比，挥发性碳氢化合物表现出不同的行为，因为它们会根据分子结构和进入海洋的环境而分配到海水或大气中。一系列不适合传统命运和运输模式的特征支配着我们对液态石油的理解。这项研究项目通过一项在自然渗漏背景下研究挥发性、水溶性碳氢化合物的计划来解决这一知识差距，重点是关于它们的运输和命运以及海洋的微生物反应的关键问题？S。两个关键问题包括：1)什么因素控制着自然渗漏时水和大气中水溶性烷烃的分配，这如何影响它们对微生物的利用？2)什么基因组和代谢因素使微生物能够对水溶性烷烃的输入做出反应，微生物的反应如何随着区域海洋和地质因素的变化而变化，例如自然渗漏的距离和通量？这些问题产生的假说将通过围绕太平洋和墨西哥湾天然石油渗漏设计的一系列海洋学和实验室实验来检验。这些研究的结果有望让我们了解海洋中水溶性烷烃的运输、命运和影响。这一裁决反映了NSF的法定使命，并通过使用基金会的智力优势和更广泛的影响审查标准进行评估，被认为值得支持。