TY - JOUR
T1 - Woodchip bioreactors provide sustained denitrification of brine from groundwater desalination plants
AU - Díaz-García, Carolina
AU - Martínez-Sánchez, Juan J.
AU - Maxwell, Bryan M.
AU - Franco, José Antonio
AU - Álvarez-Rogel, José
N1 - Funding Information:
This study was supported by the Chair of Sustainable Agriculture for the Campo de Cartagena ( Cátedra de Agricultura Sostenible para el Campo de Cartagena , https://www.catedraagriculturasostenible.es/ ). The authors thank Ana Belén Rodríguez, Ana Vanessa Caparrós, Pedro Antonio Madrid and Cristian Molina of the Technical University of Cartagena for their help and assistance in lab procedures, as well as Carlos Romero, Ibrahim Tunç, and Javier Ortigosa Castro of the same university for their help in field and lab work.
Funding Information:
This study was supported by the Chair of Sustainable Agriculture for the Campo de Cartagena (C?tedra de Agricultura Sostenible para el Campo de Cartagena, https://www.catedraagriculturasostenible.es/). The authors thank Ana Bel?n Rodr?guez, Ana Vanessa Caparr?s, Pedro Antonio Madrid and Cristian Molina of the Technical University of Cartagena for their help and assistance in lab procedures, as well as Carlos Romero, Ibrahim Tun?, and Javier Ortigosa Castro of the same university for their help in field and lab work.
Publisher Copyright:
© 2021 Elsevier Ltd
PY - 2021/7/1
Y1 - 2021/7/1
N2 - Woodchip bioreactors are widely known as a best management practice to reduce excess nitrate loads that are discharged with agricultural leachates. The aim of this study was to evaluate the performance of citrus woodchip bioreactors for denitrification of brine (electrical conductivity ≈ 17 mS cm−1) from groundwater desalination plants with high nitrate content (NO3−-N ≈ 48 mg L−1) in the Campo de Cartagena agricultural watershed, one of the main providers of horticultural products in Europe. The performance was evaluated relative to seasonal changes in temperature, dissolved organic carbon (DOC) provided by woodchips, hydraulic residence time (HRT) and woodchip aging. Bioreactors (capacity 1 m3) operated for 2.5 years (121 weeks) in batch mode (24 h HRT) with three batches per week. Denitrification efficiency was modulated by DOC concentration, temperature, hydraulic residence time and the drying-rewetting cycles. High salinity of brine did not prevent nitrate removal from occurring. The high DOC availability (>25 mg C L−1) during the first ≈48 weeks resulted in high nitrate removal rate (>75%) and nitrate removal efficiency (until ≈ 25 g N m−3 d−1) regardless of temperature. Moreover, the high DOC contents in the effluents during this period may present environmental drawbacks. Denitrification was still high after 2.5 years (reaching ≈9.3 g N m−3 d−1 in week 121), but dependence on warm temperature became more apparent with woodchips aging from week ≈49 onwards. Nitrate removal efficiency was highest on the first weekly batch, immediately after woodchips had been unsaturated for four days. It was attributable to a flush of DOC produced by aerobic microbial metabolism during drying that stimulated denitrification following re-saturation. Hence, alternance of drying-rewetting cycles is an operation practice that increase bioreactors nitrate removal performance.
AB - Woodchip bioreactors are widely known as a best management practice to reduce excess nitrate loads that are discharged with agricultural leachates. The aim of this study was to evaluate the performance of citrus woodchip bioreactors for denitrification of brine (electrical conductivity ≈ 17 mS cm−1) from groundwater desalination plants with high nitrate content (NO3−-N ≈ 48 mg L−1) in the Campo de Cartagena agricultural watershed, one of the main providers of horticultural products in Europe. The performance was evaluated relative to seasonal changes in temperature, dissolved organic carbon (DOC) provided by woodchips, hydraulic residence time (HRT) and woodchip aging. Bioreactors (capacity 1 m3) operated for 2.5 years (121 weeks) in batch mode (24 h HRT) with three batches per week. Denitrification efficiency was modulated by DOC concentration, temperature, hydraulic residence time and the drying-rewetting cycles. High salinity of brine did not prevent nitrate removal from occurring. The high DOC availability (>25 mg C L−1) during the first ≈48 weeks resulted in high nitrate removal rate (>75%) and nitrate removal efficiency (until ≈ 25 g N m−3 d−1) regardless of temperature. Moreover, the high DOC contents in the effluents during this period may present environmental drawbacks. Denitrification was still high after 2.5 years (reaching ≈9.3 g N m−3 d−1 in week 121), but dependence on warm temperature became more apparent with woodchips aging from week ≈49 onwards. Nitrate removal efficiency was highest on the first weekly batch, immediately after woodchips had been unsaturated for four days. It was attributable to a flush of DOC produced by aerobic microbial metabolism during drying that stimulated denitrification following re-saturation. Hence, alternance of drying-rewetting cycles is an operation practice that increase bioreactors nitrate removal performance.
KW - Batch bioreactors
KW - Brine management
KW - Denitrification efficiency
KW - Nitrate removal
UR - https://www.scopus.com/pages/publications/85103722088
UR - https://www.scopus.com/pages/publications/85103722088#tab=citedBy
U2 - 10.1016/j.jenvman.2021.112521
DO - 10.1016/j.jenvman.2021.112521
M3 - Article
C2 - 33839611
AN - SCOPUS:85103722088
SN - 0301-4797
VL - 289
JO - Journal of Environmental Management
JF - Journal of Environmental Management
M1 - 112521
ER -