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Evaluating Sustainable Development Pathways for Protein- and Peptide-Based Bioadsorbents for Phosphorus Recovery from Wastewater.

Justin M HutchisonFaten B HusseinBrooke K Mayer
Published in: Environmental science & technology (2023)
Recovering phosphate (P) from point sources such as wastewater effluent is a priority in order to alleviate the impacts of eutrophication and implement a circular economy for an increasingly limited resource. Bioadsorbents featuring P-binding proteins and peptides offer exquisite P specificity and sensitivity for achieving ultralow P concentrations, i.e., <100 μg P L -1 , a discharge limit that has been implemented in at least one treatment facility in nine U.S. states. To prioritize research objectives for P recovery in wastewater treatment, we compared the financial and environmental sustainability of protein/peptide bioadsorbents to those of LayneRT anion exchange resin. The baseline scenario (reflecting lab-demonstrated performance at a full-scale implementation) had costs that were 3 orders of magnitude higher than those for typical wastewater treatment. However, scenarios exploring bioadsorbent improvements, including increasing the P-binding capacity per unit volume by using smaller P-selective peptides and nanoparticle base materials and implementing reuse, dramatically decreased median impacts to $1.06 m -3 and 0.001 kg CO 2 equiv m -3 ; these values are in line with current wastewater treatment impacts and lower than the median LayneRT impacts of $4.04 m -3 and 0.19 kg CO 2 equiv m -3 . While the financial viability of capturing low P concentrations is a challenge, incorporating the externalities of environmental impacts may provide a feasible path forward to motivate ultralow P capture.
Keyphrases
  • wastewater treatment
  • antibiotic resistance genes
  • amino acid
  • healthcare
  • primary care
  • climate change
  • protein protein
  • ionic liquid
  • risk assessment
  • small molecule
  • heavy metals
  • microbial community