Fig. 1. Acetate, propionate, butyra

Fig. 1. Acetate, propionate, butyrate and valerate were
summed as VFAs.
Protein contributed about 60% of soluble TCOD in the
sludge. From Fig. 1, with the increase of ZVI from 0 to 4 g/L, the
content of soluble protein decreased from 878.2 to 341.3 mg/L,
and the soluble polysaccharide declined from 144.7 to
124.9 mg/L. The unknown organics in the supernatant also
decreased obviously. Correspondingly, as the products of the
hydrolysiseacidification, the VFAs increased from 2055.8 to
2822.1 mg/L as increasing ZVI from 0 to 4 g/L. It indicated that
the VFA production at ZVI of 4 g/L was 37.3% higher than that
of no-ZVI dosage. When further increasing ZVI to 20 g/L, the
degradations of protein and polysaccharide and the production
of VFAs had insignificant change approaching to the test
at 4 g/L. The above results suggested that the ZVI could
effectively accelerate the hydrolysiseacidification of the
sludge.
3.1.2. Composition of VFAs in the supernatant after 3 d
After the fermentation for 3 d, the VFA components under
different dosages of ZVI were detected and shown in Fig. 2.
The VFA produced mainly included acetate, propionate,
butyrate and valerate, and acetate was the prevailing product.
At the dosages of 0, 1, 4 and 20 g/L, the acetate concentration
was 759.2, 971.0, 1373.2 and 1303.1 mg/L and its percentage in
the total VFAs was 36.9%, 41.3%, 48.7% and 47.5%, respectively.
It indicated that ZVI could enhance the acetate production.
The result was in agreement with our previous report, in
which with the addition of ZVI the acetate production from
the anaerobic digestion of sucrose in solution increased 20%
(Liu et al., 2012b). The maximal acetate production occurred at
ZVI of 4 g/L, 80.9% higher than that of no-ZVI dosage. It also
can be seen that the percentage of propionate decreased from
20.6% to 11.7% with the increase of ZVI from 0 to 4 g/L. It is well
known that acetic-type, propionic-type and butyric-type
fermentation are three major fermenting pathways in anaerobic
digestion. The butyric-type fermentation converts
organic matters to butyric and acetic acids, and the propionictype
fermentation mainly produces propionic acid, whereas
the acetic-type fermentation may directly decompose organics
to acetate. Propionic-type fermentation is believed as a
facultative anaerobic process occurring at an ORP higher than
278 mV, while acetic-type and butyric-type fermentation are
obligate anaerobic processes occurring at a more negative ORP
(Ren et al., 2007; Wang et al., 2006). ZVI as a reductivematerial
could create a more reductive atmosphere to enhance butyrictype
and acetic-type fermentation and to decline propionate
production. Meng et al. (2013) reported that propionate conversion
rate increased from 43e77% to 67e89% by ZVI addition.
It might be one reason for the increase of acetate and
decrease of propionate, which might provide a favorable
substrate form for methanogenesis.
3.1.3. Total protein and polysaccharide in the remainder
sludge and mass balance calculation after 3 d
As shown in Fig. 3, the sludge used in this experiment contained
6820.5 mg-COD/L of protein and 1332.1 mg-COD/L of
polysaccharide, accounting for 63.0% and 12.3% of organic
matters in the sludge, respectively. At ZVI of 0, 1, 4 and 20 g/L,
after the fermentation for 3 d, the total protein was reduced to
5077.4, 4723.5, 4317.1 and 4330 mg/L, respectively, and the
total polysaccharide was reduced to 1028.6, 1008.6, 937.8 and
939.6 mg/L, respectively. It meant that the highest decomposition
ratio of protein and polysaccharide, happening at the
dosage of 4 g/L, was 36.7% and 29.6%, respectively. The
decomposition of these two complex organics at the dosage of
20 g/L approached to that of 4 g/L. Their decomposition with
no ZVI was slowest, only 25.6% for total protein and 22.9% for
polysaccharide. The results were in agreement with the production
of VFAs in the supernatant. It further suggested ZVI
accelerated the hydrolysiseacidification of sludge.
A mass balance based on COD was conducted after 3 d
fermentation (see Fig. S1A in Supplementary material). The
COD in the sludge anaerobic digestion included the COD from
solid organic matters, soluble hydrolysis products (hydrolysate)
produced from the alkaline-pretreatment, VFA, methane
and others products. Before the fermentation, solid organic
matters and hydrolysate produced from the alkalinepretreatment
were the prevalent component, accounting for
60.0% and 37.3% of total organics, respectively. After the
fermentation, the maximum ratio of solid sludge hydrolysis
(or solubilization) and VFA accumulation, achieving at 4 g/L of