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UNS: Collaborative Research: Measurement and Modeling of the Pathways of Potential Fugitive Methane Emissions During Hydrofracking

UNS：合作研究：水力压裂过程中潜在逃逸甲烷排放路径的测量和建模

基本信息

批准号：
1717142
负责人：
Jaclyn Matthes
金额：
$ 5.92万
依托单位：
Wellesley College
依托单位国家：
美国
项目类别：
Continuing Grant
财政年份：
2016
资助国家：
美国
起止时间：
2016-11-14 至 2019-07-31
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1717142&HistoricalAwards=false
关键词：
UNS Collaborative Research Measurement Modeling

项目摘要

1508994(Bohrer) & 1509297(Matthes)Production of natural gas from deep subsurface shale formations in the US has increased considerably in the last decade due to the advancement in drilling and hydraulic fracturing technology. In 2010, shale gas accounted for 23% of annual dry natural gas supply in the US, with projections that this capacity will increase to 48% by 2035. There are large economic advantages of shale gas development, including reliance on domestic production due to the abundance of natural gas in the US and the improved air quality when using natural gas compared with the combustion of gas and coal. This project will examine fugitive emissions, those not controlled in the production well, in a life cycle analyses of the greenhouse gas footprint that include the hydrofracking extraction and production processes.The development of shale gas resources in the United States is predicted to grow steadily over the next twenty years, however there is large uncertainty surrounding the quantity and mechanisms of fugitive methane emissions released to the atmosphere from these activities. The large range among methane measurements from different hydrofracking sites suggests that fugitive emissions may be largely preventable and are dependent on the practices of the drill and well operators. This project will provide a much needed and timely set of baseline and fugitive methane emission measurements before and during hydrofracking operations that will quantify and identify the sources of methane emissions released during different components of the drilling and gas extraction operations process. This will fill a critical knowledge gap that will inform the development of effective management strategies and operations practices to minimize methane emissions and improve the overall greenhouse gas benefits of natural gas. This project will: (1) Quantify baseline and fugitive methane emissions during hydrofracking by collecting continuous landscape-scale methane flux measurements; (2) Identify biological and geological sources of methane emissions by measuring continuous atmospheric fluxes of 13C isotopes in methane; (3) Attribute measured methane fluxes to different components of the hydrofracking process by using a footprint model and advanced large eddy simulations to isolate flux sources in space and time. This project will leverage ongoing collaboration with the Ohio State University Shale Energy and Environment Field Laboratory (SEEL), which will provide the site access to drilling operations and information about the management practices and operations timeline will be provided through the SEEL partnership with the drill and well operators. The PIs will partner with the Ohio State University (OSU) Extension Office to develop online and print resources and forums for the general public describing the effects of shale gas development on local and regional air and water quality. They will also work with OSU Extension to transfer results from this project to hydrofracking practitioners who could use information regarding drill pad management practices to effectively reduce fugitive methane emissions. The PIs will share the developed products with West Virginia University and Extension, with whom they extensively collaborate on shale gas development issues. Furthermore, they will leverage existing outreach relationships with the Ohio Water Resources Center to present the work related to this project at a water luncheon organized with the Water Management Association of Ohio, and at a separate seminar to state agency representatives. A graduate student will be trained in observation and modeling methods for methane fluxes during this project. This project will also train undergraduate students from the Dartmouth Women in Science Program in fieldwork and data analyses to develop honors theses from this research.

1508994（Bohrer）1509297（Matthes）由于钻井和水力压裂技术的进步，美国深层地下页岩层的天然气产量在过去十年中大幅增加。2010年，页岩气占美国干天然气年供应量的23%，预计到2035年这一能力将增加到48%。页岩气开发有很大的经济优势，包括依赖国内生产，因为美国天然气丰富，与天然气和煤炭燃烧相比，使用天然气可以改善空气质量。该项目将在包括水力压裂开采和生产过程在内的温室气体足迹的生命周期分析中，检查生产井中未控制的散逸性排放。美国页岩气资源的开发预计将在未来20年内稳步增长，然而，围绕这些活动释放到大气中的散逸性甲烷排放的数量和机制存在很大的不确定性。来自不同水力压裂现场的甲烷测量值之间的大范围表明，散逸性排放在很大程度上是可以预防的，并且取决于钻井和钻井操作员的实践。该项目将在水力压裂作业之前和期间提供一套急需和及时的基准和逃逸甲烷排放测量，这些测量将量化和确定钻井和天然气开采作业过程中不同组成部分释放的甲烷排放源。这将填补一个关键的知识空白，为制定有效的管理战略和运营做法提供信息，以尽量减少甲烷排放并提高天然气的总体温室气体效益。该项目将：（2）通过测量甲烷中13 C同位素的连续大气通量，确定甲烷排放的生物和地质来源;（三）通过使用足迹模型和先进的大涡模拟来隔离通量，将测量的甲烷通量归因于水力压裂过程的不同组件空间和时间的来源。该项目将利用与俄亥俄州州立大学页岩能源与环境现场实验室（SEEL）的持续合作，SEEL将为现场提供钻井作业的访问权限，并将通过SEEL与钻井和油井运营商的合作伙伴关系提供有关管理实践和运营时间轴的信息。PI将与俄亥俄州州立大学（OSU）推广办公室合作，为公众开发在线和印刷资源和论坛，描述页岩气开发对当地和区域空气和水质的影响。他们还将与俄勒冈州立大学扩展部合作，将该项目的结果转移给水力压裂从业者，他们可以使用有关钻井平台管理实践的信息来有效减少逃逸性甲烷排放。PI将与西弗吉尼亚大学和推广部门分享开发的产品，并与他们在页岩气开发问题上进行广泛合作。此外，他们将利用与俄亥俄州水资源中心的现有外联关系，在与俄亥俄州水管理协会组织的水午餐会上介绍与该项目相关的工作，并在单独的研讨会上向州机构代表介绍。在该项目期间，一名研究生将接受甲烷通量观察和建模方法的培训。该项目还将培训来自达特茅斯女性科学项目的本科生进行实地考察和数据分析，以从这项研究中撰写荣誉论文。