监测、核查和核算地质二氧化碳储存项目的关键作用

Q2 Earth and Planetary Sciences Environmental Geosciences Pub Date : 2011-03-01 DOI:10.1306/EG.06231010008
S. Plasynski, J. Litynski, H. Mcilvried, Derek M. Vikara, R. Srivastava
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引用次数: 21

摘要

人们越来越担心大气中温室气体含量的增加会导致全球气候变化,这促使人们寻找既经济又环保的方法来减少二氧化碳的排放。一种很有前景的方法是将二氧化碳捕获并永久储存在深层地质构造中,如枯竭的油气储层、无法开采的煤层和深层含盐水(含盐)地层。然而,地质储存项目的成功实施需要强大的监测、验证和核算(MVA)工具。本文涉及与此类地质CO2封存项目相关的MVA活动的各个方面,包括场地特征、CO2羽流跟踪、CO2流速和注入压力监测、泄漏检测、盖层岩石完整性分析以及长期注入后监测。改进的详细决策树图涵盖了地质储存工程的五个阶段。这些图表提供了从选址到施工和运营到关闭和关闭后监测的指导。讨论了适用于各个项目阶段的监测、验证和会计技术(既有已建立的,也有前景的新发展)。美国能源部(DOE)区域碳封存伙伴关系现场项目的成就是MVA工具(如二维和三维地震和微地震)开发和应用于地质储存的例子,以及新型成本效益监测技术的测试。尽管将MVA和计算机模拟工作仔细结合起来以确保地质储存项目的长期成功是很重要的,但本文仅限于讨论MVA活动。这篇文章是2009年美国能源部国家能源技术实验室发表的一篇报告的延伸,题为“监测、验证和计算深层地质构造中储存的二氧化碳的最佳实践”,有兴趣的读者可以参考该报告了解MVA工具的更多细节。最终,一个强有力的MVA项目对于将碳捕获和封存作为一项可行的温室气体减排战略至关重要。
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The critical role of monitoring, verification, and accounting for geologic carbon dioxide storage projects
A growing concern that increasing levels of greenhouse gases in the atmosphere are contributing to global climate change has led to a search for economical and environmentally sound ways to reduce carbon dioxide (CO2) emissions. One promising approach is CO2 capture and permanent storage in deep geologic formations, such as depleted oil and gas reservoirs, unminable coal seams, and deep brine-containing (saline) formations. However, successful implementation of geologic storage projects will require robust monitoring, verification, and accounting (MVA) tools. This article deals with all aspects of MVA activities associated with such geologic CO2 storage projects, including site characterization, CO2 plume tracking, CO2 flow rate and injection pressure monitoring, leak detection, cap-rock integrity analysis, and long-term postinjection monitoring. Improved detailed decision tree diagrams are presented covering the five stages of a geologic storage project. These diagrams provide guidance from the point of site selection through construction and operations to closure and postclosure monitoring. Monitoring, verification, and accounting techniques (both well-established and promising new developments) appropriate for various project stages are discussed. Accomplishments of the Department of Energy (DOE) Regional Carbon Sequestration Partnerships field projects serve as examples of the development and application to geologic storage of MVA tools, such as two-dimensional and three-dimensional seismic and microseismic, as well as the testing of new cost-effective monitoring technologies. Although it is important that MVA and computer simulation efforts be carefully integrated to ensure long-term success of geologic storage projects, this article is limited to a discussion of MVA activities. This article is an extension of a report published in 2009 by the DOE National Energy Technology Laboratory titled, “Best Practices for Monitoring, Verification, and Accounting of CO2 Stored in Deep Geologic Formations,” to which interested readers are referred for more details on MVA tools. Ultimately, a robust MVA program will be critical for establishing carbon capture and storage as a viable greenhouse gas mitigation strategy.
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Environmental Geosciences
Environmental Geosciences Earth and Planetary Sciences-Earth and Planetary Sciences (all)
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