posted on 2024-02-15, 18:04authored byShi Chen, Lai Peng, Yifeng Xu, Ning Wang, Xi Wang, Chuanzhou Liang, Kang Song, Yan Zhou
Sidestream serves as an important reservoir collecting
pharmaceuticals
from sludge. However, the knowledge on sidestream pharmaceutical removal
is still insufficient. In this work, atenolol biodegradation during
sidestream partial nitritation (PN) processes characterized by high
free nitrous acid (FNA) accumulation was modeled. To describe the
FNA inhibition on ammonia oxidation and atenolol removal, Vadivelu-type
and Hellinga-type inhibition kinetics were introduced into the model
framework. Four inhibitory parameters along with four biodegradation
kinetic parameters were calibrated and validated separately with eight
sets of batch experimental data and 60 days’ PN reactor operational
data. The developed model could accurately reproduce the dynamics
of nitrogen and atenolol. The model prediction further revealed that
atenolol biodegradation efficiencies by ammonia-oxidizing bacteria
(AOB)-induced cometabolism, AOB-induced metabolism, and heterotrophic
bacteria-induced biodegradation were 0, ∼ 60, and ∼35%
in the absence of ammonium and FNA; ∼ 14, ∼ 29, and
∼28% at 0.03 mg-N L–1 FNA; and 7, 15, and
5% at 0.19 mg-N L–1 FNA. Model simulation showed
that the nitritation efficiency of ∼99% and atenolol removal
efficiency of 57.5% in the PN process could be achieved simultaneously
by controlling pH at 8.5, while 89.2% total nitrogen and 57.1% atenolol
were removed to the maximum at pH of 7.0 in PN coupling with the anammox
process. The pH-based operational strategy to regulate FNA levels
was mathematically demonstrated to be effective for achieving the
simultaneous removal of nitrogen and atenolol in PN-based sidestream
processes.