Elucidating phosphorus removal dynamics in a denitrifying woodchip bioreactor

Gimhani N Perera; Dorisel Torres Rojas; Aldrin Rivas; Greg Barkle; Brian Moorhead; Louis A Schipper; Rupert Craggs; Adam Hartland

doi:10.1016/j.scitotenv.2024.170478

Elucidating phosphorus removal dynamics in a denitrifying woodchip bioreactor

Sci Total Environ. 2024 Mar 20:917:170478. doi: 10.1016/j.scitotenv.2024.170478. Epub 2024 Jan 30.

Authors

Gimhani N Perera¹, Dorisel Torres Rojas², Aldrin Rivas³, Greg Barkle⁴, Brian Moorhead³, Louis A Schipper², Rupert Craggs⁵, Adam Hartland⁶

Affiliations

¹ Environmental Research Institute, School of Science, Faculty of Science and Engineering, University of Waikato, Kirikirioa Hamilton, New Zealand; National Institute of Water and Atmospheric Research Ltd (NIWA), PO Box 11115, Kirikirioa Hamilton 3251, New Zealand.
² Environmental Research Institute, School of Science, Faculty of Science and Engineering, University of Waikato, Kirikirioa Hamilton, New Zealand.
³ Lincoln Agritech Ltd, Ruakura, Kirikirioa Hamilton 3214, New Zealand.
⁴ Land and Water Research Ltd, Kirikirioa Hamilton 3217, New Zealand.
⁵ National Institute of Water and Atmospheric Research Ltd (NIWA), PO Box 11115, Kirikirioa Hamilton 3251, New Zealand.
⁶ Environmental Research Institute, School of Science, Faculty of Science and Engineering, University of Waikato, Kirikirioa Hamilton, New Zealand; Lincoln Agritech Ltd, Ruakura, Kirikirioa Hamilton 3214, New Zealand. Electronic address: adam.hartland@waikato.ac.nz.

PMID: 38301780
DOI: 10.1016/j.scitotenv.2024.170478

Abstract

Denitrifying woodchip bioreactors (DBRs) are an established nitrate mitigation technology, but uncertainty remains on their viability for phosphorus (P) removal due to inconsistent source-sink behaviour in field trials. We investigated whether iron (Fe) redox cycling could be the missing link needed to explain P dynamics in these systems. A pilot-scale DBR (Aotearoa New Zealand) was monitored for the first two drainage seasons (2017-2018), with supplemental in-field measurements of reduced solutes (Fe²⁺, HS^-/H₂S) and their conjugate oxidised species (Fe³⁺/SO₄^2-) made in 2021 to constrain within-reactor redox gradients. Consistent with thermodynamics, the dissolution of Fe³⁺_(s) to Fe²⁺₍_aq₎ within the DBR sequentially followed O₂, NO₃^- and MnO₂_(s) reduction, but occurred before SO₄^2- reduction. Monitoring of inlet and outlet chemistry revealed tight coupling between Fe and P (inlet R² 0.94, outlet R² 0.85), but distinct dynamics between drainage seasons. In season one, outlet P exceeded inlet P (net P source), and coincided with elevated outlet Fe²⁺, but at ⁓50 % lower P concentrations relative to inlet Fe:P ratios. In season 2 the reactor became a net P sink, coinciding with declining outlet Fe²⁺ concentrations (indicating exhaustion of Fe³⁺_(s) hydroxides and associated P). In order to characterize P removal under varying source dynamics (i.e. inflows vs in-situ P releases), we used the inlet Fe vs P relationship to estimate P binding to colloidal Fe (hydr)oxide surfaces under oxic conditions, and the outlet Fe²⁺ concentration to estimate in-situ P releases associated with Fe (hydr)oxide reduction. Inferred P-removal rates were highest early in season 1 (k = 0.60 g P m³ d^-1; 75-100 % removal), declining significantly thereafter (k = 0.01 ± 0.02 g P m³ d^-1; ca. 3-67 % removal). These calculations suggest that microbiological P removal in DBRs can occur at comparable magnitudes to nitrate removal by denitrification, depending mainly on P availability and hydraulic retention efficiency.

Keywords: Biogeochemical cycles; Biological uptake; Denitrifying woodchip bioreactor; Phosphorus.

MeSH terms

Bioreactors
Denitrification
Manganese Compounds
Nitrates*
Nitrogen
Oxides
Phosphorus*

Substances

Phosphorus
Nitrates
Manganese Compounds
Oxides
Nitrogen