Savannah River Ecology Laboratory, University of Georgia , P.O. Drawer E, Aiken, South Carolina 29802, United States.
Environ Sci Technol. 2014 Aug 19;48(16):9270-8. doi: 10.1021/es5015136. Epub 2014 Jul 29.
The hypothesis of this study was that iron plaques formed on the roots of wetland plants and their rhizospheres create environmental conditions favorable for iron reducing bacteria that promote the in situ immobilization of uranium. Greenhouse microcosm studies were conducted using native plants (Sparganium americanum) from a wetland located on the Savannah River Site, Aiken, SC. After iron plaques were established during a 73-day period by using an anoxic Fe(II)-rich nutrient solution, a U(VI) amended nutrient solution was added to the system for an additional two months. Compared to plant-free control microcosms, microcosms containing iron plaques successfully stimulated the growth of targeted iron reducing bacteria, Geobacter spp. Their population continuously increased after the introduction of the U(VI) nutrient solution. The reduction of some of the U(VI) to U(IV) by iron reducing bacteria was deduced based on the observations that the aqueous Fe(II) concentrations increased while the U(VI) concentrations decreased. The Fe(II) produced by the iron reducing bacteria was assumed to be reoxidized by the oxygen released from the roots. Advanced spectroscopic analyses revealed that a significant fraction of the U(VI) had been reduced to U(IV) and they were commonly deposited in association with phosphorus on the iron plaque.
本研究的假设是,湿地植物的根部及其根际形成的铁斑为铁还原菌创造了有利的环境条件,从而促进铀的原位固定。本研究采用来自南卡罗来纳州艾肯萨凡纳河场址的本地植物(美国三棱草)进行温室微宇宙研究。在使用缺氧富铁营养溶液建立铁斑 73 天后,向系统中添加了含有 U(VI)的营养溶液,再持续两个月。与无植物对照微宇宙相比,含有铁斑的微宇宙成功地刺激了目标铁还原菌(Geobacter spp.)的生长。在引入 U(VI)营养溶液后,其种群数量不断增加。根据观察到的水溶液中 Fe(II)浓度增加而 U(VI)浓度降低的情况,推断出部分 U(VI)被铁还原菌还原为 U(IV)。假定铁还原菌产生的 Fe(II)被根释放的氧气重新氧化。高级光谱分析表明,相当一部分 U(VI)已被还原为 U(IV),并与铁斑上的磷共同沉积。
