TY - JOUR
T1 - Advancements in biofilm carriers and gas-permeable membranes
T2 - assessment of zeolite technologies for shortcut nitrogen removal applications in wastewater
AU - Huff Chester, Anndee L.
AU - Romero-Vargas Castrillón, Santiago
AU - Novak, Paige J.
N1 - Publisher Copyright:
© 2023 The Royal Society of Chemistry.
PY - 2023/3/29
Y1 - 2023/3/29
N2 - The partial nitrification-anammox (PNA) process and other shortcut nitrogen removal processes have been widely studied because of their potential to offer cost savings during wastewater treatment; nevertheless, sustainable examples of full-scale mainstream shortcut nitrogen removal are lacking. The recent development of novel biofilm supports, specifically, zeolite-coated hollow fiber membranes and zeolite-coated biofilm carriers, that locally concentrate ammonium are promising for enhancing mainstream PNA. The ideal application of these technologies is yet to be determined, however. In this study, zeolite-coated carriers were tested in flow-through reactors under both anaerobic and aerobic conditions and zeolite-coated hollow fiber membranes were tested in a membrane-aerated flow-through configuration with varying operating times, lumen oxygen concentrations, and with the presence and absence of amended nitrite. Under anaerobic conditions, reactors containing zeolite-coated carriers had significantly greater ammonium and total nitrogen (TN) removal (84.0 ± 16.2% and 89.4 ± 17.1%, respectively) compared to reactors containing control carriers (P = 0.005). Anaerobic ammonia oxidizing (anammox) bacteria-specific 16S rRNA (Amx) genes and two genes associated with denitrifiers (nirS and nosZ) were preferentially retained in the bulk liquid and in the carrier biofilms in zeolite-coated carrier reactors at a statistically significant level. Genes specific to aerobic ammonium oxidizers (amoA genes) were preferentially retained in the bulk liquid of the zeolite-coated carrier reactors. The aerated zeolite-coated carrier reactors also had higher ammonium removal rates (83.8 ± 10.9%) and higher TN removal rates (69.1 ± 16.1%) compared to the aerated control reactors (30.8 ± 23.4%, P = 0.002 and 37.4 ± 27.4%, P = 0.05 for ammonia and TN, respectively). Again, despite aeration, amoA genes were only preferentially retained in the liquid of the reactors containing zeolite-coated carriers. In experiments with zeolite-coated membranes, Amx genes were preferentially retained at significantly higher quantities under only two of the experimental conditions: two-week operation with 100% oxygen delivered in the membrane lumen and two-week operation with nitrite supplemented in the influent. Overall, the zeolite-coated carriers present promising potential for deployment in both anaerobic and aerated environments to enhance nitrogen removal and, in particular, the retention of anammox bacteria. The zeolite-coated membranes require more study before their optimal deployment strategy is clear.
AB - The partial nitrification-anammox (PNA) process and other shortcut nitrogen removal processes have been widely studied because of their potential to offer cost savings during wastewater treatment; nevertheless, sustainable examples of full-scale mainstream shortcut nitrogen removal are lacking. The recent development of novel biofilm supports, specifically, zeolite-coated hollow fiber membranes and zeolite-coated biofilm carriers, that locally concentrate ammonium are promising for enhancing mainstream PNA. The ideal application of these technologies is yet to be determined, however. In this study, zeolite-coated carriers were tested in flow-through reactors under both anaerobic and aerobic conditions and zeolite-coated hollow fiber membranes were tested in a membrane-aerated flow-through configuration with varying operating times, lumen oxygen concentrations, and with the presence and absence of amended nitrite. Under anaerobic conditions, reactors containing zeolite-coated carriers had significantly greater ammonium and total nitrogen (TN) removal (84.0 ± 16.2% and 89.4 ± 17.1%, respectively) compared to reactors containing control carriers (P = 0.005). Anaerobic ammonia oxidizing (anammox) bacteria-specific 16S rRNA (Amx) genes and two genes associated with denitrifiers (nirS and nosZ) were preferentially retained in the bulk liquid and in the carrier biofilms in zeolite-coated carrier reactors at a statistically significant level. Genes specific to aerobic ammonium oxidizers (amoA genes) were preferentially retained in the bulk liquid of the zeolite-coated carrier reactors. The aerated zeolite-coated carrier reactors also had higher ammonium removal rates (83.8 ± 10.9%) and higher TN removal rates (69.1 ± 16.1%) compared to the aerated control reactors (30.8 ± 23.4%, P = 0.002 and 37.4 ± 27.4%, P = 0.05 for ammonia and TN, respectively). Again, despite aeration, amoA genes were only preferentially retained in the liquid of the reactors containing zeolite-coated carriers. In experiments with zeolite-coated membranes, Amx genes were preferentially retained at significantly higher quantities under only two of the experimental conditions: two-week operation with 100% oxygen delivered in the membrane lumen and two-week operation with nitrite supplemented in the influent. Overall, the zeolite-coated carriers present promising potential for deployment in both anaerobic and aerated environments to enhance nitrogen removal and, in particular, the retention of anammox bacteria. The zeolite-coated membranes require more study before their optimal deployment strategy is clear.
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U2 - 10.1039/d3ew00211j
DO - 10.1039/d3ew00211j
M3 - Article
AN - SCOPUS:85153517626
SN - 2053-1400
VL - 9
SP - 1354
EP - 1370
JO - Environmental Science: Water Research and Technology
JF - Environmental Science: Water Research and Technology
IS - 5
ER -