4.5 Article

Ammonia oxidizing bacteria and archaea in horizontal flow biofilm reactors treating ammonia-contaminated air at 10 °C

Journal

Publisher

OXFORD UNIV PRESS
DOI: 10.1007/s10295-016-1740-z

Keywords

Ammonia oxidation; Ammonia oxidising bacteria; Ammonia oxidising archaea; Nitrification: low-temperature, HFBR (horizontal flow biofilm reactor)

Funding

  1. Science Foundation Ireland [08/RFP/ENM1762]
  2. European Research Council (3C-BIOTECH) [261330]
  3. Science Foundation Ireland (SFI) [08/RFP/ENM1762] Funding Source: Science Foundation Ireland (SFI)
  4. European Research Council (ERC) [261330] Funding Source: European Research Council (ERC)

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The objective of this study was to demonstrate the feasibility of novel, Horizontal Flow Biofilm Reactor (HFBR) technology for the treatment of ammonia (NH3)-contaminated airstreams. Three laboratory-scale HFBRs were used for remediation of an NH3-containing airstream at 10 A degrees C during a 90-d trial to test the efficacy of low-temperature treatment. Average ammonia removal efficiencies of 99.7 % were achieved at maximum loading rates of 4.8 g NH3 m(3) h(-1). Biological nitrification of ammonia to nitrite (NO2 (-)) and nitrate (NO3 (-)) was mediated by nitrifying bacterial and archaeal biofilm populations. Ammonia-oxidising bacteria (AOB) were significantly more abundant than ammonia-oxidising archaea (AOA) vertically at each of seven sampling zones along the vertical HFBRs. Nitrosomonas and Nitrosospira, were the two most dominant bacterial genera detected in the HFBRs, while an uncultured archaeal clone dominated the AOA community. The bacterial community composition across the three HFBRs was highly conserved, although variations occurred between HFBR zones and were driven by physicochemical variables. The study demonstrates the feasibility of HFBRs for the treatment of ammonia-contaminated airstreams at low temperatures; identifies key nitrifying microorganisms driving the removal process; and provides insights for process optimisation and control. The findings are significant for industrial applications of gas oxidation technology in temperate climates.

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