深钻孔处置核废料:机遇与挑战

F. Schwartz, Yongje Kim, B. Chae
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引用次数: 4

摘要

高放核废料深孔处置(DBD)的概念已经出现了大约40年。现在,美国能源部(DOE)正在通过桑迪亚国家实验室(Sandia National Laboratory)最近的研究和现场测试重新审视这一概念。利用DBD,核废料将被安置在3至5公里深的结晶基底岩石的钻孔中。我们的想法是,这些设置将提供几乎完整的岩石和流体密度分层,它们一起应该充当坚固的地质屏障,只需要最小的工程组件性能。核废料技术审查委员会(NWTRB)已经提出了担忧,认为地下深处更为复杂,会导致科学、工程和安全问题。然而,考虑到时间和资源,DBD在钻深孔并在那里进行测量的能力上将会有很大的发展。钻探技术的飞跃可能会带来其他令人兴奋的地质应用。可能的创新可能包括深层机器人采矿,深层能源生产,或二氧化碳的地壳封存,以及核废料处理的新想法。韩国地质学家可以通过简单的概念验证实验和技术演示来探索新技术。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deep Borehole Disposal of Nuclear Wastes: Opportunities and Challenges
The concept of deep borehole disposal (DBD) for high-level nuclear wastes has been around for about 40 years. Now, the Department of Energy (DOE) in the United States (U.S.) is re-examining this concept through recent studies at Sandia National Laboratory and a field test. With DBD, nuclear waste will be emplaced in boreholes at depths of 3 to 5 km in crystalline basement rocks. Thinking is that these settings will provide nearly intact rock and fluid density stratification, which together should act as a robust geologic barrier, requiring only minimal performance from the engineered components. The Nuclear Waste Technical Review Board (NWTRB) has raised concerns that the deep subsurface is more complicated, leading to science, engineering, and safety issues. However, given time and resources, DBD will evolve substantially in the ability to drill deep holes and make measurements there. A leap forward in technology for drilling could lead to other exciting geological applications. Possible innovations might include deep robotic mining, deep energy production, or crustal sequestration of CO2, and new ideas for nuclear waste disposal. Novel technologies could be explored by Korean geologists through simple proof-of-concept experiments and technology demonstrations.
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