the PHA levels. In contrast, B0 inc

the PHA levels. In contrast, B0 increased (p< 0.05) with increasing PHA levels, from 192 to 274 L CH4/kg VS
(increased by 43%) when the PHA levels increased from 21 to 143 mg/g VS. This suggests that PHA-based method
could enhance biochemical methane potential of WAS. Correspondingly, the calculated Y increased (p< 0.05)
from 0.42 to 0.59 while the PHA levels increased from 21 to 143 mg/g VS, revealing that WAS degradation was
improved by 43%. tlag (7± 1 d) was similar (p> 0.05) in all PHA levels, indicating that PHA levels applied would
not affect lag time.
95% confidence regions of k1 and k2, k1 and B0, and k2 and B0, were determined to assess their identifiability.
The linear confidence intervals (error bars) exceeded the non-linear regions (ellipses) due to the fact that the
former was the estimates via four-parameter prediction while the latter was predicted via two-parameter prediction by fixing the other two parameters. The higher degree of freedom and increased localized error function in
four-parameter estimation might lead to the over-estimation of the linear confidence intervals19. Nevertheless,
the overall 95% confidence regions for the three pairs shown in Fig. 2 are small, with mean values lying at the
center. This indicates that the parameters are well identifiable and the estimated values are reliable. Figure 2 shows
that the 95% confidence regions of k1 and k2 almost fully overlapped in the studied PHA levels, suggesting that
PHA levels would not significantly affect hydrolysis rate. In contrast, the 95% confidence regions of k1 and B0, and
k
2 and B0, moved rightward to the higher B0 direction with the increasing PHA levels, revealing that the higher
biochemical methane potential can be achieved at the higher PHA levels.
Discussion
PHA-based method enhances biochemical methane potential instead of hydrolysis rate. There
are two key parameters related to anaerobic methane production, biochemical methane potential (B0) and first
order hydrolysis rate (k), which represent the extent and speed of anaerobic methane production, respectively.
This study showed that the PHA-based method enhances anaerobic methane production through improving B0
instead of k. Indeed, a linear relationship between PHA levels and B0 was observed (see Fig. 3). This is for the
first time that the mechanisms for the PHA improved methane production were revealed. Although Huda et al.18
demonstrated that the PHA-based method could enhance anaerobic methane production, their study was not
systematic and only one PHA level was used. Also, the underlying mechanisms were not revealed in their study.
However, it should be highlighted that microbiological analyses will be required in the future to further reveal
the mechanisms.
In general, the waste activated sludge (WAS) mainly consisted of protein and carbohydrate. During anaerobic
digestion, 1 g of protein (C4H6.1O1.2N, equivalent to 1.53 g of COD) and carbohydrate (C6H10O5, equivalent to
1.18 g of COD) can theoretically produce methane at 0.59 and 0.45 L CH4, respectively20. In contrast, 1 g of PHA
(C4H6O2, equivalent to 1.67 g of COD) can theoretically generate more CH4 (0.65 L CH4/g PHA) in comparison
with protein and carbohydrate21. Therefore, if WAS contains more PHA, higher biochemical methane potential
would be achieved. This might account for the PHA improved biochemical methane potential of WAS.
The unchanged k revealed in this work indicates that the performance improvement would be impossible or
very limited in hydraulically limited anaerobic digesters. However, for anaerobic digesters with a long hydraulic
retention time (HRT), the increased B0 would drive the enhancement of methane production in the anaerobic
digesters.
It has been widely reported that PHA can be accumulated in the main-stream wastewater treatment process by ordinary heterotrophic organisms, polyphosphate-accumulating organisms and glycogen-accumulating
organisms12–17. The PHA-rich organisms/sludge would then be subject to anaerobic digestion. However, PHA
degradation is not taken into account in the current Anaerobic Digestion Model No. 1 (ADM1)22. This might lead
to an underestimation of methane generation especially for the anaerobic digester receiving PHA-rich sludge.
Therefore, the current ADM1 should be modified to include PHA degradation in the future.
Potential economic benefit of PHA-based method to enhance anaerobic methane production.
The results of laboratory BMP tests have been shown to be more conservative or comparable to those of full-scale
trials23. Consequently, the experimental results attained in this work via the lab-scale BMP tests could be used
conservatively for predicting the economic potential of the proposed PHA-based method. This was conducted
via a desktop scaling-up study in a WWTP with a population equivalent (PE) of 400,000 and with an anaerobic
digester at an HRT of 20 d. Figure 1 shows that WAS with PHA at 143 mg/g VS obtained the largest methane
production at a