Stratus Consulting, Boulder, CO 80302, USA.
J Hazard Mater. 2012 Apr 30;213-214:474-7. doi: 10.1016/j.jhazmat.2012.02.029. Epub 2012 Feb 19.
A sediment microbial fuel cell (MFC) was tested to determine if electron transfer from the anaerobic zone of contaminated sediments to the overlying aerobic water could facilitate an enhanced and aerobic equivalent degradation of total petroleum hydrocarbons (TPH). Results indicate that voltages as high as 190 mV (2162 mW/m(3)) were achieved in a sediment MFC with an anode buried in sediments containing TPH concentrations at approximately 16,000 mg kg(-1). Additionally, after approximately 66 days, the TPH degradation rates were 2% and 24% in the open-circuit control sediment MFC and active sediment MFC, respectively. Therefore, it appears that applying MFC technology to contaminated sediments enhances natural biodegradation by nearly 12 fold. Additionally, a novel sediment MFC was designed to provide a cost-effective method of passive oxidation or indirect aerobic degradation of contaminants in an otherwise anaerobic environment. In addition, the use of a wicking air cathode in this study maintained dissolved oxygen concentrations 1-2 mg l(-1) higher than submerged cathodes, demonstrating that this technology can be applied to environments with either aerobic or anaerobic overlying water and an anaerobic matrix, such as shallow lagoon, ponds, and marshes, and groundwater.
采用沉积物微生物燃料电池(MFC)来检测从受污染沉积物的厌氧区向覆盖的好氧水传递电子是否能够促进总石油烃(TPH)的增强和好氧等效降解。结果表明,在阳极埋置于 TPH 浓度约为 16000mgkg-1的沉积物中的沉积物 MFC 中,可实现高达 190mV(2162mW/m3)的电压。此外,在大约 66 天后,开路控制沉积物 MFC 和活性沉积物 MFC 中的 TPH 降解率分别为 2%和 24%。因此,似乎将 MFC 技术应用于受污染的沉积物可将自然生物降解率提高近 12 倍。此外,设计了一种新型的沉积物 MFC,以提供一种在其他厌氧环境中对污染物进行被动氧化或间接好氧降解的具有成本效益的方法。此外,在本研究中使用吸水空气阴极可将溶解氧浓度维持在比淹没阴极高 1-2mgL-1,这表明该技术可应用于具有好氧或厌氧上覆水和厌氧基质(如浅泻湖、池塘和沼泽地)以及地下水的环境中。
