摘要

A multiple bio-cathodes constructed wetland-microbial fuel cell (CW-MFC) system, aiming for higher power production and therefore the improved N removal, was investigated in this study. As the bio-cathode number increased from 1 to 3, the energy losses on both anode and cathode showed a significant decrement (from 97.85mV to 46.09mV for anode and from 221.5mV to 45.89mV for cathode, respectively). Accordingly, the maximum power density of the system showed a notable increase from12.56 to 26.16mW/m(2). In addition to the improved electrical performance, enhanced simultaneous nitrification & denitrification process was triggered due to the influence of the bioelectrical derived interaction between power production and systematic nitrification rate (rNi) and denitrification rate (rDe). Insight into the nitrification & denitrification process has been given that rNi increased from 98.59 +/- 4.53mg/(m(2 center dot)d) of the control system to 179.11 +/- 7.65mg/(m(2 center dot)d) of three bio-cathodes system while r(De) increased from 89.64 +/- 4.57mg/(m(2 center dot) d) to 163.55 +/- 11.88 mg/(m(2 center dot)d). Correction analysis showed that the amount of electrical related nitrogen removal is almost linearly correlated to the produced electricity. Overall, this study presented a promising strategy and provided insight for higher energy production and the enhanced nitrogen removal from the newly established CW-MFC system.