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Impact of microforms on nitrate transport at the groundwater –surface water interface

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Impact of microforms on nitrate transport at the groundwater –surface water interface. / Hu, Haizhu; Binley, Andrew; Heppell, Catherine et al.
In: Advances in Water Resources, Vol. 73, 11.2014, p. 185-197.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Hu, H, Binley, A, Heppell, C, Lansdown, K & Mao, X 2014, 'Impact of microforms on nitrate transport at the groundwater –surface water interface', Advances in Water Resources, vol. 73, pp. 185-197. https://doi.org/10.1016/j.advwatres.2014.07.013

APA

Vancouver

Hu H, Binley A, Heppell C, Lansdown K, Mao X. Impact of microforms on nitrate transport at the groundwater –surface water interface. Advances in Water Resources. 2014 Nov;73:185-197. Epub 2014 Aug 8. doi: 10.1016/j.advwatres.2014.07.013

Author

Hu, Haizhu ; Binley, Andrew ; Heppell, Catherine et al. / Impact of microforms on nitrate transport at the groundwater –surface water interface. In: Advances in Water Resources. 2014 ; Vol. 73. pp. 185-197.

Bibtex

@article{ac11f5e17b564c03a4c0dd99504313be,
title = "Impact of microforms on nitrate transport at the groundwater –surface water interface",
abstract = "Small streambed structures (or microforms, 0.01-1 m in length) exist ubiquitously in riverbed systems. Small-scale topography is potentially important in controlling hyporheic exchange flow and transport of conservative and reactive solutes at the groundwater-surface water interface. The role of microforms on NO3- transfer in a riffle-scale (macroforms of > 1 m length) hyporheic zone within a gaining river setting is investigated using a 2-D flow and transport model which accounts for both nitrification and denitrification. Results show that the short pathlines caused by microforms lead to more NO3- discharge to the river compared with a macroform-only condition due to shortened residence times of both surface water and groundwater in mixing zones. Short hyporheic exchange flow pathways caused by microforms could remain oxic along their entire length or switch from nitrate producing to nitrate consuming as oxygen concentrations decline. Microforms affect net NO3- flux by the combined effect of introducing more stream mass flux and reducing their residence time in mixing zones under different hydrological and biogeochemical conditions. Our findings underscore that ignoring microforms in river beds may underestimate NO3- load to the river and have practical implications for porewater sampling strategies in groundwater-surface water studies.",
keywords = "Hyporheic flow, Nitrate transfer, Riffle-pool sequence, Microform, Nitrification, Denitrification",
author = "Haizhu Hu and Andrew Binley and Catherine Heppell and Katrina Lansdown and Xiaomin Mao",
note = "Date of Acceptance: 28/07/2014",
year = "2014",
month = nov,
doi = "10.1016/j.advwatres.2014.07.013",
language = "English",
volume = "73",
pages = "185--197",
journal = "Advances in Water Resources",
issn = "0309-1708",
publisher = "Elsevier Limited",

}

RIS

TY - JOUR

T1 - Impact of microforms on nitrate transport at the groundwater –surface water interface

AU - Hu, Haizhu

AU - Binley, Andrew

AU - Heppell, Catherine

AU - Lansdown, Katrina

AU - Mao, Xiaomin

N1 - Date of Acceptance: 28/07/2014

PY - 2014/11

Y1 - 2014/11

N2 - Small streambed structures (or microforms, 0.01-1 m in length) exist ubiquitously in riverbed systems. Small-scale topography is potentially important in controlling hyporheic exchange flow and transport of conservative and reactive solutes at the groundwater-surface water interface. The role of microforms on NO3- transfer in a riffle-scale (macroforms of > 1 m length) hyporheic zone within a gaining river setting is investigated using a 2-D flow and transport model which accounts for both nitrification and denitrification. Results show that the short pathlines caused by microforms lead to more NO3- discharge to the river compared with a macroform-only condition due to shortened residence times of both surface water and groundwater in mixing zones. Short hyporheic exchange flow pathways caused by microforms could remain oxic along their entire length or switch from nitrate producing to nitrate consuming as oxygen concentrations decline. Microforms affect net NO3- flux by the combined effect of introducing more stream mass flux and reducing their residence time in mixing zones under different hydrological and biogeochemical conditions. Our findings underscore that ignoring microforms in river beds may underestimate NO3- load to the river and have practical implications for porewater sampling strategies in groundwater-surface water studies.

AB - Small streambed structures (or microforms, 0.01-1 m in length) exist ubiquitously in riverbed systems. Small-scale topography is potentially important in controlling hyporheic exchange flow and transport of conservative and reactive solutes at the groundwater-surface water interface. The role of microforms on NO3- transfer in a riffle-scale (macroforms of > 1 m length) hyporheic zone within a gaining river setting is investigated using a 2-D flow and transport model which accounts for both nitrification and denitrification. Results show that the short pathlines caused by microforms lead to more NO3- discharge to the river compared with a macroform-only condition due to shortened residence times of both surface water and groundwater in mixing zones. Short hyporheic exchange flow pathways caused by microforms could remain oxic along their entire length or switch from nitrate producing to nitrate consuming as oxygen concentrations decline. Microforms affect net NO3- flux by the combined effect of introducing more stream mass flux and reducing their residence time in mixing zones under different hydrological and biogeochemical conditions. Our findings underscore that ignoring microforms in river beds may underestimate NO3- load to the river and have practical implications for porewater sampling strategies in groundwater-surface water studies.

KW - Hyporheic flow

KW - Nitrate transfer

KW - Riffle-pool sequence

KW - Microform

KW - Nitrification

KW - Denitrification

U2 - 10.1016/j.advwatres.2014.07.013

DO - 10.1016/j.advwatres.2014.07.013

M3 - Journal article

VL - 73

SP - 185

EP - 197

JO - Advances in Water Resources

JF - Advances in Water Resources

SN - 0309-1708

ER -