Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/3622
Title: Comparative study of anammox-mediated nitrogen removal in three reactor configurations
Authors: Kosgey, Kiprotich Eric 
Keywords: Plug-flow;Mixing;ANAMMOX;Reactor configuration;Biofilms;Suspended biomass
Issue Date: 27-May-2021
Abstract: 
Anaerobic ammonium oxidation (ANAMMOX) is an efficient and cost-effective process
developed for biological nitrogen removal from wastewater. However, widespread
application of the ANAMMOX process for wastewater treatment remains constrained due
to the slow growth of ANAMMOX bacteria, propensity for out-competition by fast growing
microbes, and its sensitivity to environmental and operational conditions. Consequently,
understanding the influence of mixing conditions in different reactor configurations on this
process is paramount in its improvement.
This study focused on the comparative analysis of ANAMMOX-mediated nitrogen removal
in a hybrid up-flow anaerobic sludge blanket reactor (H-UASB), moving bed biofilm reactor
(MBBR) and a gas-lift reactor (GLR). The study involved experimental study of nitrogen
removal, bacterial population dynamics and physical properties of the bacterial biomass
within the reactors, as well as the description of process performance and the growth of
nitrifying and ANAMMOX bacteria in the reactors using a calibrated mechanistic model.
All the reactors were operated for 535 days using the same synthetic feed under anaerobic
conditions. K1-type carrier materials were added to each reactor for biofilm development.
The concentrations of ammonium (NH4
+
), nitrite (NO2
-
) and nitrate (NO3
-
) in the effluent
from the reactors were determined colorimetrically. Among the three reactors, MBBR
displayed the highest nitrogen removal efficiency (NRE) during the study (66±36%), and
contained the lowest concentration of free ammonia (FA) (19±22 mg-N/L) and free nitrous
acid (FNA) (0.001±0.001 mg-N/L). In comparison, the NRE and the concentrations of FA
and FNA in H-UASB during the study were 63±28%, 91±41 mg-N/L and 0.006±0.004 mgN/L, respectively, while in the GLR, they were 54±39%, 28±29 mg-N/L and 0.002±0.002
mg-N/L, respectively. Based on the ratios of NO2
-
consumed to NH4
+
consumed, and the
ratios of NO3
-
produced to NH4
+
consumed, the start-up of ANAMMOX process was faster
in the MBBR (144 days) compared to H-UASB (193 days) and GLR (272 days). MBBR
also displayed less fluctuations in the NREs and nitrogen removal rates (NRRs) during the
study compared to H-UASB and GLR.
The microbial communities in the suspended biomass in the reactors were characterised
using high-throughput sequencing on an Illumina MiSeq platform on days 125, 192, 260,
309 and 535, while the microbial communities in the biofilms were only characterised on
day 535 (last day) due to slow biofilm development. Gradual increases in the relative abundance of ANAMMOX bacteria were observed in the suspended biomass in all the
reactors between days 125 and 309, which corroborated the observed increases in the NREs.
The relative abundance of ANAMMOX bacteria remained consistently higher in H-UASB
during the study than in MBBR and GLR. On the contrary, the highest relative abundance
of ammonia oxidising bacteria (AOB) was observed in the suspended biomass in the MBBR
on day 125 at approximately 38%, while the highest relative abundance of nitrite oxidising
bacteria (NOB) and complete ammonia oxidising (COMAMMOX) bacteria was recorded in
the suspended biomass in the MBBR at approximately 30% and 5%, respectively. In all the
reactors, the relative abundance of AOB in the biofilms and the suspended biomass was
comparable on day 535. In addition, on day 535, higher relative abundance of NOB was
observed in the biofilms in both GLR and H-UASB at approximately 7% compared to the
suspended biomass, while their abundance in the suspended biomass in the MBBR was
comparable to that recorded in the biofilms. Furthermore, in both H-UASB and MBBR,
higher relative abundance of ANAMMOX bacteria was observed in the suspended biomass
compared to the biofilms on day 535, while comparable abundance was observed in the
GLR. The highest total microbial diversity (Shannon and Simpson indices) and evenness
(Pielou’s Evenness) was observed in the suspended biomass in the MBBR.
Granulation of the suspended biomass was observed in both GLR and H-UASB, while the
suspended biomass in the MBBR was flocculent. In the MBBR, the colour of the biomass
had turned brown on day 125, while the biomass in H-UASB and GLR on this day was
tawny and dark-tawny, respectively. However, on day 309, the biomass in all the reactors
had turned red, corroborating the highest relative abundance of ANAMMOX bacteria
observed during the study. Faster attachment of biomass on the carrier materials in MBBR
was observed in the course of study compared to H-UASB and GLR. On the last day, the
concentrations of the biomass on the carrier materials in the MBBR was also higher (12
mg/carrier) in the MBBR than in the H-UASB (8 mg/carrier) and GLR (10 mg/carrier).
Activated sludge model 1 (ASM 1), which was modified by separating the activities of
Nitrospira spp. from those of Nitrobacter spp. as well as by adding both ANAMMOX and
COMAMMOX bacterial activities, was used to describe process performance in the reactors.
The modified ASM 1 was able to predict the trends in the effluent concentrations of NH4
+
,
NO2
-
and NO3
-
in all the reactors. In addition, the correlation of the actual relative abundance
of nitrifying and ANAMMOX bacteria, with the model-predicted relative abundance, was
positive. The model also indicated higher heterotrophic activities in both GLR and MBBR compared to H-UASB, an indication that continuous mixing in MBBR and alternation of
plug-flow conditions with internal gas circulation in GLR favoured heterotrophic bacterial
growth. However, the model was limited in predicting the fluctuations in bacterial
abundance and the fluctuations in the effluent concentrations of NH4
+
, NO2
-
and NO3
-
in the
reactors.
The obtained results indicate that better-mixed conditions in the MBBR led to comparable
relative abundance of nitrifying bacteria between the biofilms and the suspended biomass,
while plug-flow conditions in the H-UASB favoured ANAMMOX bacterial growth in the
suspended biomass and the nitrifying bacterial growth in the biofilms. The alternation of
internal gas circulation with plug-flow conditions in the GLR also favoured the growth of
nitrifying bacteria in the biofilms. Overall, nitrogen removal in H-UASB was likely
dominated by ANAMMOX process, while nitrogen removal in MBBR and GLR was as a
result of combined ANAMMOX and sequential nitrification-denitrification processes. The
novelty of this study stem from the impact of mixing conditions on process performance and
microbial ecology of ANAMMOX-mediated systems.
Description: 
Thesis submitted in fulfilment of the requirements for the Degree of Doctor of Engineering: Chemical Engineering, Durban University of Technology, 2021.
URI: https://hdl.handle.net/10321/3622
DOI: https://doi.org/10.51415/10321/3622
Appears in Collections:Theses and dissertations (Engineering and Built Environment)

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