Abstract
In this work, the metabolic uncoupler para-nitrophenol (pNP) was applied to suppress excess sludge production and to investigate its effects on the system’s performance and activated sludge community structure. The COD removal efficiency decreased from 99.0% to 89.5% prior to and after pNP addition, respectively. Application of pNP transiently reduced NH4+-N, NO3−-N and NO2−-N removal efficiencies, suggesting partial inhibition of both nitrifying and denitrifying activity. However, no changes in the relative abundance of the nitrifying bacteria occurred. Phosphorus removal efficiency was sharply reduced after pNP addition, as the consequence of hydrolysis of stored cell reserves. Tetrasphaera, a key polyphosphate accumulating organism, was also affected by the addition of pNP, a fact that highly influenced system’s ability to remove phosphorus. A drastic drop in Soluble Microbial Products (SMP) and Extracellular Polymeric Substances (EPS) was also detected shortly after the introduction of the uncoupler. On the other hand, MBR’s physicochemical parameters were restored to initial values a week after the addition of pNP. Moreover, remarkable changes in beta-diversity were noted after pNP addition. An increase of Bacteroidetes, Gammaproteobacteria and Firmicutes over Actinobacteria and Alphaproteobacteria was also observed after pNP addition.
Highlights
Nowadays, activated sludge is the most recognized process in municipal and industrial wastewater treatment, due to its simplicity and high nutrient removal efficiency.activated sludge systems produce a high amount of excess sludge as a byproduct of the process [1]
An membrane bioreactor (MBR) is a modified activated sludge system, where the separation of solids is accomplished without using a secondary clarifier [4]
A transient reduction in biosolids concentration was observed after pNP addition, resulting in Mixed liquor suspended solids (MLSS) and mixed liquor volatile suspended solids (MLVSS) content as low as 4070 and 3540 respectively (Figure 2a)
Summary
Nowadays, activated sludge is the most recognized process in municipal and industrial wastewater treatment, due to its simplicity and high nutrient removal efficiency. Activated sludge systems produce a high amount of excess sludge as a byproduct of the process [1]. Excess sludge treatment is of high cost since it itself accounts for up to 60% of the total operating costs in biological nutrient removal systems, due to the stricter regulations for effluent disposal [2,3]. Main benefits of the MBR over the conventional activated sludge process include less excess sludge production and higher effluent quality. MBRs can operate under higher biosolids concentration than the conventional activated sludge systems, favoring a lower foodto-microorganism ratio and less sludge production [5]. Ding et al [6] focused on the effect of the chemical uncoupler
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