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Intensive Microalgal Cultivation and Tertiary Phosphorus Recovery from Wastewaters via the EcoRecover Process.

Hannah R MolitorGa-Yeong KimElaine HartnettBenjamin GincleyMd Mahbubul AlamJianan FengNickolas M AvilaAutumn FisherMahdi HodaeiYalin LiKevin McGrawRoland D CusickIan M BradleyAmeet J PintoJeremy S Guest
Published in: Environmental science & technology (2024)
Mixed community microalgal wastewater treatment technologies have the potential to advance the limits of technology for biological nutrient recovery while producing a renewable carbon feedstock, but a deeper understanding of their performance is required for system optimization and control. In this study, we characterized the performance of a 568 m 3 ·day -1 Clearas EcoRecover system for tertiary phosphorus removal (and recovery as biomass) at an operating water resource recovery facility (WRRF). The process consists of a (dark) mix tank, photobioreactors (PBRs), and a membrane tank with ultrafiltration membranes for the separation of hydraulic and solids residence times. Through continuous online monitoring, long-term on-site monitoring, and on-site batch experiments, we demonstrate (i) the importance of carbohydrate storage in PBRs to support phosphorus uptake under dark conditions in the mix tank and (ii) the potential for polyphosphate accumulation in the mixed algal communities. Over a 3-month winter period with limited outside influences (e.g., no major upstream process changes), the effluent total phosphorus (TP) concentration was 0.03 ± 0.03 mg-P·L -1 (0.01 ± 0.02 mg-P·L -1 orthophosphate). Core microbial community taxa included Chlorella spp. , Scenedesmus spp. , and Monoraphidium spp. , and key indicators of stable performance included near-neutral pH, sufficient alkalinity, and a diel rhythm in dissolved oxygen.
Keyphrases
  • wastewater treatment
  • microbial community
  • antibiotic resistance genes
  • sewage sludge
  • anaerobic digestion
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