Bioremediation Options for Nuclear Sites a Review of an Emerging Technology

IF 0.4 Q4 NUCLEAR SCIENCE & TECHNOLOGY Journal of Nuclear Fuel Cycle and Waste Technology Pub Date : 2022-09-30 DOI:10.7733/jnfcwt.2022.026

Callum Robinson, White Matthew, S. Shaw, K. Morris, J. Graham, J. Lloyd

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引用次数: 1

Abstract

60+ Years of nuclear power generation has led to a significant legacy of radioactively contaminated land at a number of nuclear licenced “mega sites” around the world. The safe management and remediation of these sites is key to ensuring there environmental stewardship in the long term. Bioremediation utilizes a variety of microbially mediated processes such as, enzymatically driven metal reduction or biominerialisation, to sequester radioactive contaminants from the subsurface limiting their migration through the geosphere. Additionally, some of these process can provide environmentally stable sinks for radioactive contaminants, through formation of highly insoluble mineral phases such as calcium phosphates and carbonates, which can incorporate a range of radionuclides into their structure. Bioremediation options have been consid - ered and deployed in preference to conventional remediation techniques at a number of nuclear “mega” sites. Here, we review the applications of bioremediation technologies at three key nuclear licenced sites; Rifle and Hanford, USA and Sellafield, UK, in the remediation of radioactively contaminated land.

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核设施生物修复方案:一项新兴技术综述

60多年的核能发电导致了世界各地许多核许可“大型站点”的放射性污染土地的重要遗产。这些地点的安全管理和补救是确保长期环境管理的关键。生物修复利用各种微生物介导的过程，如酶驱动的金属还原或生物矿化，从地下隔离放射性污染物，限制其通过地圈的迁移。此外，通过形成高度不溶的矿物相，例如磷酸钙和碳酸盐，其中一些过程可以为放射性污染物提供环境稳定的汇，这些矿物相可以将一系列放射性核素纳入其结构中。在一些核“巨型”场址，生物修复方案已被考虑并优先于传统修复技术进行部署。在此，我们回顾了生物修复技术在三个关键核许可站点的应用;来福尔和汉福德，美国和塞拉菲尔德，英国，在放射性污染的土地修复。

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来源期刊

Journal of Nuclear Fuel Cycle and Waste Technology Energy-Fuel Technology

CiteScore

0.80

自引率

25.00%

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