factors affecting electron and mate

factors affecting electron and material transport influence MFC
performance, including the size and shape of the electrodes (20),
modification of the anode chemical properties (21,22), and the
condition of the biofilm on the anode electrode (23). Investigations
focused on these factors will improve not only electricity productivity
but also acetic acid productivity.
The OCV of the MFC was detected as soon as the fermentation
suspension was injected into the anode chamber of the MFC. The
OCVs increased with the total fermentation time and reached a
maximum value of 0.521 V prior to the third batch fermentation,
which might have resulted from the formation of an A. aceti biofilm
on the anode surface during the long fermentation. The OCV
decreased to 0.441 V after the third batch fermentation. This result
suggested that the activity of cells in the biofilm decreased during
the third batch fermentation. In the first and second batch fermentations,
measurement of the ieV relationship of the MFC
showed that the polarizations during the current production period
of the MFC measured after batch fermentation were smaller than
those measured before fermentation (Figs. 1, 3 and 4a). Therefore,
the maximum current and power densities in this study (19.1 mA/
cm2 and 2.47 mW/cm2, respectively) were obtained after the second
batch fermentation. The low polarization after batch fermentation
was mainly due to the decrease in the overpotential of the anode
(Figs. 1, 3 and 4b). The unsteady voltage and current profiles in the
initial period of fermentation (Figs. 2 and 6b) showed that A. aceti
required time to adapt to the new fermentation conditions. After
the batch fermentation, A. aceti cells were better adapted to the
fermentation conditions than they had been before fermentation.
Therefore, the adapted cells might be able to produce and accumulate
more electrons via the conversion of ethanol to acetic acid.