The small-size organic matters are

The small-size organic matters are further converted to
VFAs with the function of acid-forming enzyme such as AK,
PTA, BK and PTB. Specifically, PTA and PTB can decompose
acetyl-CoA and butyryl-CoA to acetyl and butyryl phosphate,
respectively, and then are further converted to acetate and
butyrate with the function of AK and BK, respectively. As
shown in Table 2, the dosage of ZVI significantly improved the
activities of these key enzymes above. The activities of protease
and cellulose at the dosage of 20 g/L increased 92.0% and
91.7%, respectively. It was a reason for the higher performance
in the hydrolysis of protease and cellulose with the presence
of ZVI. The activities of acid-forming enzymes including AK,
PTA, BK and PTB increased about 57%e83% at ZVI of 20 g/L. It
was in agreement with the accelerated decomposition of VFAs
and more acetate production during the acidification.
3.4. FISH analysis for hydrogen-consuming
microorganisms
Acetogenesis of fatty acids may happen if hydrogen is not
accumulated but is consumed by hydrogen-consuming microorganisms
(Appels et al., 2008). FISH was used to analyze
the major hydrogen-consuming microorganisms including
homoacetogens and hydrogenotrophic methanogens. The
abundance of homoacetogens in bacteria was 38.3% at ZVI of
20 g/L, while it was only 23.8% at no dosage of ZVI (see Fig. S3
in Supplementary material). The abundance of hydrogenotrophic
methanogens in archaea was 77.7% at 20 g/L
compared to 54.3% without ZVI. It further proved that ZVI
enhanced the growth of hydrogen-consuming microorganisms,
thereby improving the production of acetate or
methane.
3.5. Possibility of using scrap iron
The function of ZVI was assumedly depended on the surface
reaction of ZVI, i.e. Fe0þ2Hþ ¼ Fe2þþH2. Increase of the dosage
provided a bigger surface to release more Fe2þ. From this point
of view, the waste scrap iron widely existing in machinery
industriesmay be used as ZVI. A possible doubt of utilizing the
scrap iron is that the scrap has a small surface area. However,
the scrap iron usually with a size of about decimeter level
possibly had a better mass transfer in the high concentration
sludge under mixing condition. Comparatively, the powder
iron was easily immersed into sludge to slow down its function.
The released Fe2þ at 20 g/L of dosage was only 80 mg/L
after 20 d, while Fe2þ reached 15.7 mg/L when the scrap iron
was used in anaerobic system with a HRT of 2 d in our previous
study (Liu et al., 2012b). It suggested that mass transfer in
the surface of the scrap did not decrease but increase. More
importantly, the scrap iron is more compatible for application.
Apart from its lower cost, the scrap is more convenient to be
recycled than the powder. The further investigation on the
scrap iron would be conducted in the next study. Nevertheless,
the study provided a novel and useful method to accelerate
the anaerobic sludge digestion and to enhance methane
production.
4. Conclusions
The anaerobic digestion of sludge was limited by the low
rate of hydrolysis and acidification. This study showed that
the anaerobic digestion of sludge was accelerated by the
addition of ZVI. The production of VFAs was enhanced by
37.3% with ZVI during the hydrolysis and acidification. After
the digestion for 20 d, the methane productivity at ZVI of
20 g/L increased by 43.5%, and the sludge reduction ratio
increased by 12.2 percent points. The reasons could be
ascribed to the following aspects. Firstly, the activities of
major enzymes related to hydrolysis and acidification were
enhanced after adding ZVI. It made the digestion better
catalyzed in the conversion of solid sludge and other complex
organics to VFAs. Secondly, ZVI could enhance the
growth of H2-utilizing microorganisms including homoacetogens
and hydrogenotrophic methanogens to consume H2
and then drive the anaerobic digestion.