在微生物燃料电池中进行铜回收与电能生产相结合。

Copper recovery combined with electricity production in a microbial fuel cell.

机构信息

Sub-Department of Environmental Technology, Wageningen University, Bomenweg, 6700 EV Wageningen, The Netherlands.

出版信息

Environ Sci Technol. 2010 Jun 1;44(11):4376-81. doi: 10.1021/es100526g.

PMID:20462261

Abstract

A metallurgical microbial fuel cell (MFC) is an attractive alternative for recovery of copper from copper containing waste streams, as the metal is recovered in its metallic form at the cathode, while the energy for metal reduction can be obtained from oxidation of organic materials at the anode with possible additional production of electricity. We studied the recovery of copper in an MFC using a bipolar membrane as a pH separator. Under anaerobic conditions, the maximum power density was 0.43 W/m(2) at a current density of 1.7 A/m(2). In the presence of oxygen, MFC performance improved considerably to a maximum power density of 0.80 W/m(2) at a current density of 3.2 A/m(2). Pure copper crystals were formed on the cathode, and no CuO or Cu(2)O was detected. Removal efficiencies of >99.88% were obtained. The cathodic recovery of copper compared to the produced electricity was 84% (anaerobic) and 43% (aerobic). The metallurgy MFC with the Cu(2+) reducing cathode further enlarges the application range of MFCs.

摘要

一种冶金微生物燃料电池（MFC）是从含铜废水中回收铜的一种很有吸引力的替代方法，因为金属在阴极以金属形式回收，而金属还原所需的能量可以通过阳极有机材料的氧化获得，并且可能有额外的电力生产。我们研究了使用双极膜作为 pH 分离器的 MFC 中铜的回收。在厌氧条件下，最大功率密度为 0.43 W/m²，电流密度为 1.7 A/m²。在有氧存在的情况下，MFC 的性能大大提高，最大功率密度为 0.80 W/m²，电流密度为 3.2 A/m²。在阴极上形成了纯铜晶体，没有检测到 CuO 或 Cu(2)O。去除效率>99.88%。与产生的电量相比，阴极回收的铜为 84%（厌氧）和 43%（有氧）。带有 Cu(2+)还原阴极的冶金 MFC 进一步扩大了 MFC 的应用范围。

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在微生物燃料电池中进行铜回收与电能生产相结合。

Copper recovery combined with electricity production in a microbial fuel cell.

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