Time to anoxia: Observations and predictions of oxygen drawdown following coastal flood events

Kaizad F. Patel; Kenton A. Rod; Jianqiu Zheng; Peter Regier; Fausto Machado-Silva; Ben Bond-Lamberty; Xingyuan Chen; Donnie J. Day; Kennedy O. Doro; Matthew H. Kaufman; Matthew Kovach; Nate McDowell; Sophia A. McKever; J. Patrick Megonigal; Cooper G. Norris; Teri O'Meara; Roberta B. Peixoto; Roy Rich; Peter Thornton; Kenneth M. Kemner; Nick D. Ward; Michael N. Weintraub; Vanessa L. Bailey

doi:10.1016/j.geoderma.2024.116854

Time to anoxia: Observations and predictions of oxygen drawdown following coastal flood events

Kaizad F. Patel
, Kenton A. Rod
, Jianqiu Zheng
, Peter Regier
, Fausto Machado-Silva
, Ben Bond-Lamberty
, Xingyuan Chen
, Donnie J. Day
, Kennedy O. Doro
, Matthew H. Kaufman
, Matthew Kovach
, Nate McDowell
, Sophia A. McKever
, J. Patrick Megonigal
, Cooper G. Norris
, Teri O'Meara
, Roberta B. Peixoto
, Roy Rich
, Peter Thornton
, Kenneth M. Kemner

Nick D. Ward, Michael N. Weintraub, Vanessa L. Bailey

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

The coastal terrestrial-aquatic interface (TAI) is a highly dynamic system characterized by strong physical, chemical, and biological gradients. In particular, shifting soil redox conditions and consumption of terminal electron acceptors, due in part to dynamic hydrologic conditions, is a strong driver of carbon availability and transformations across TAIs. However, while redox dynamics are well described, our ability to quantitatively forecast rates of oxic to anoxic shifts in soils with different characteristics and inundation regimes is limited. We integrated field measurements, laboratory incubations, and model simulations to improve mechanistic understanding of oxygen consumption dynamics in coastal soils. Continuous in situ monitoring unexpectedly revealed that flooding caused temporary spikes in subsurface dissolved oxygen followed by rapid consumption in the wetlands. To further investigate these mechanisms in a controlled setting, we performed laboratory incubations using surface and subsurface soils from a TAI gradient (defined here as upland forest to transitional forest to wetland) in Western Lake Erie to measure oxygen consumption rates in TAI soils during flood events. In our experiments, wetland soils reached anoxia the fastest, in ∼ 9 h on average, whereas upland soils turned anoxic in ∼ 18 h. Subsurface upland soils did not turn anoxic even after two weeks of saturation in the lab, and their oxygen consumption patterns suggested carbon and/or nutrient limitation. These results are consistent with in-situ groundwater redox and oxygen measurements in the field, where wetland soils exhibited the highest rates of oxygen consumption along the TAI. Model simulations of oxygen consumption suggested that oxygen consumption had stronger abiotic controls in wetland soils but stronger biotic controls in upland soils, providing a useful framework for future incubation experiments. Microbial activity is a strong driver of oxygen consumption in TAI soils, although it is constrained by the availability of dissolved carbon in subsurface soils.

Original language	English
Article number	116854
Journal	Geoderma
Volume	444
DOIs	https://doi.org/10.1016/j.geoderma.2024.116854
State	Published - Apr 2024

Funding

This work was supported through the Field, Measurements, and Experiments (FME) component of the Coastal Observations, Mechanisms, and Predictions Across Systems and Scales (COMPASS) program ( https://compass.pnnl.gov/ ). COMPASS-FME is a multi-institutional project supported by the US Department of Energy, Office of Science, Biological and Environmental Research as part of the Environmental System Science Program. This project is led by Pacific Northwest National Laboratory which is operated for DOE by Battelle Memorial Institute under contract DE-AC05-76RL01830. This work was also supported by the Smithsonian Environmental Research Center. We thank Devon Fields and Jared Musci for their assistance in the lab. We thank Steven McMurray and Janice Kerns at the OWC/ODNR for facilitating site access. Old Woman Creek National Estuarine Research Reserve is located on Kaskaskia Land. The descendants of the Kaskaskia are now enrolled in the Peoria Tribe of Indians of Oklahoma, a federally recognized tribe in Oklahoma. We recognize and respect the Kaskaskia as the traditional stewards of this land.

Keywords

Anoxia
Groundwater
Model-experiment integration
Soil
Wetlands

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10.1016/j.geoderma.2024.116854

Cite this

Patel, K. F., Rod, K. A., Zheng, J., Regier, P., Machado-Silva, F., Bond-Lamberty, B., Chen, X., Day, D. J., Doro, K. O., Kaufman, M. H., Kovach, M., McDowell, N., McKever, S. A., Megonigal, J. P., Norris, C. G., O'Meara, T., Peixoto, R. B., Rich, R., Thornton, P., ... Bailey, V. L. (2024). Time to anoxia: Observations and predictions of oxygen drawdown following coastal flood events. Geoderma, 444, Article 116854. https://doi.org/10.1016/j.geoderma.2024.116854

@article{acab75ef9222419d9a550d477eedebb8,

title = "Time to anoxia: Observations and predictions of oxygen drawdown following coastal flood events",

abstract = "The coastal terrestrial-aquatic interface (TAI) is a highly dynamic system characterized by strong physical, chemical, and biological gradients. In particular, shifting soil redox conditions and consumption of terminal electron acceptors, due in part to dynamic hydrologic conditions, is a strong driver of carbon availability and transformations across TAIs. However, while redox dynamics are well described, our ability to quantitatively forecast rates of oxic to anoxic shifts in soils with different characteristics and inundation regimes is limited. We integrated field measurements, laboratory incubations, and model simulations to improve mechanistic understanding of oxygen consumption dynamics in coastal soils. Continuous in situ monitoring unexpectedly revealed that flooding caused temporary spikes in subsurface dissolved oxygen followed by rapid consumption in the wetlands. To further investigate these mechanisms in a controlled setting, we performed laboratory incubations using surface and subsurface soils from a TAI gradient (defined here as upland forest to transitional forest to wetland) in Western Lake Erie to measure oxygen consumption rates in TAI soils during flood events. In our experiments, wetland soils reached anoxia the fastest, in ∼ 9 h on average, whereas upland soils turned anoxic in ∼ 18 h. Subsurface upland soils did not turn anoxic even after two weeks of saturation in the lab, and their oxygen consumption patterns suggested carbon and/or nutrient limitation. These results are consistent with in-situ groundwater redox and oxygen measurements in the field, where wetland soils exhibited the highest rates of oxygen consumption along the TAI. Model simulations of oxygen consumption suggested that oxygen consumption had stronger abiotic controls in wetland soils but stronger biotic controls in upland soils, providing a useful framework for future incubation experiments. Microbial activity is a strong driver of oxygen consumption in TAI soils, although it is constrained by the availability of dissolved carbon in subsurface soils.",

keywords = "Anoxia, Groundwater, Model-experiment integration, Soil, Wetlands",

author = "Patel, \{Kaizad F.\} and Rod, \{Kenton A.\} and Jianqiu Zheng and Peter Regier and Fausto Machado-Silva and Ben Bond-Lamberty and Xingyuan Chen and Day, \{Donnie J.\} and Doro, \{Kennedy O.\} and Kaufman, \{Matthew H.\} and Matthew Kovach and Nate McDowell and McKever, \{Sophia A.\} and Megonigal, \{J. Patrick\} and Norris, \{Cooper G.\} and Teri O'Meara and Peixoto, \{Roberta B.\} and Roy Rich and Peter Thornton and Kemner, \{Kenneth M.\} and Ward, \{Nick D.\} and Weintraub, \{Michael N.\} and Bailey, \{Vanessa L.\}",

note = "Publisher Copyright: {\textcopyright} 2024",

year = "2024",

month = apr,

doi = "10.1016/j.geoderma.2024.116854",

language = "English",

volume = "444",

journal = "Geoderma",

issn = "0016-7061",

publisher = "Elsevier",

}

Patel, KF, Rod, KA, Zheng, J, Regier, P, Machado-Silva, F, Bond-Lamberty, B, Chen, X, Day, DJ, Doro, KO, Kaufman, MH, Kovach, M, McDowell, N, McKever, SA, Megonigal, JP, Norris, CG, O'Meara, T, Peixoto, RB, Rich, R, Thornton, P, Kemner, KM, Ward, ND, Weintraub, MN & Bailey, VL 2024, 'Time to anoxia: Observations and predictions of oxygen drawdown following coastal flood events', Geoderma, vol. 444, 116854. https://doi.org/10.1016/j.geoderma.2024.116854

TY - JOUR

T1 - Time to anoxia

T2 - Observations and predictions of oxygen drawdown following coastal flood events

AU - Patel, Kaizad F.

AU - Rod, Kenton A.

AU - Zheng, Jianqiu

AU - Regier, Peter

AU - Machado-Silva, Fausto

AU - Bond-Lamberty, Ben

AU - Chen, Xingyuan

AU - Day, Donnie J.

AU - Doro, Kennedy O.

AU - Kaufman, Matthew H.

AU - Kovach, Matthew

AU - McDowell, Nate

AU - McKever, Sophia A.

AU - Megonigal, J. Patrick

AU - Norris, Cooper G.

AU - O'Meara, Teri

AU - Peixoto, Roberta B.

AU - Rich, Roy

AU - Thornton, Peter

AU - Kemner, Kenneth M.

AU - Ward, Nick D.

AU - Weintraub, Michael N.

AU - Bailey, Vanessa L.

PY - 2024/4

Y1 - 2024/4

N2 - The coastal terrestrial-aquatic interface (TAI) is a highly dynamic system characterized by strong physical, chemical, and biological gradients. In particular, shifting soil redox conditions and consumption of terminal electron acceptors, due in part to dynamic hydrologic conditions, is a strong driver of carbon availability and transformations across TAIs. However, while redox dynamics are well described, our ability to quantitatively forecast rates of oxic to anoxic shifts in soils with different characteristics and inundation regimes is limited. We integrated field measurements, laboratory incubations, and model simulations to improve mechanistic understanding of oxygen consumption dynamics in coastal soils. Continuous in situ monitoring unexpectedly revealed that flooding caused temporary spikes in subsurface dissolved oxygen followed by rapid consumption in the wetlands. To further investigate these mechanisms in a controlled setting, we performed laboratory incubations using surface and subsurface soils from a TAI gradient (defined here as upland forest to transitional forest to wetland) in Western Lake Erie to measure oxygen consumption rates in TAI soils during flood events. In our experiments, wetland soils reached anoxia the fastest, in ∼ 9 h on average, whereas upland soils turned anoxic in ∼ 18 h. Subsurface upland soils did not turn anoxic even after two weeks of saturation in the lab, and their oxygen consumption patterns suggested carbon and/or nutrient limitation. These results are consistent with in-situ groundwater redox and oxygen measurements in the field, where wetland soils exhibited the highest rates of oxygen consumption along the TAI. Model simulations of oxygen consumption suggested that oxygen consumption had stronger abiotic controls in wetland soils but stronger biotic controls in upland soils, providing a useful framework for future incubation experiments. Microbial activity is a strong driver of oxygen consumption in TAI soils, although it is constrained by the availability of dissolved carbon in subsurface soils.

AB - The coastal terrestrial-aquatic interface (TAI) is a highly dynamic system characterized by strong physical, chemical, and biological gradients. In particular, shifting soil redox conditions and consumption of terminal electron acceptors, due in part to dynamic hydrologic conditions, is a strong driver of carbon availability and transformations across TAIs. However, while redox dynamics are well described, our ability to quantitatively forecast rates of oxic to anoxic shifts in soils with different characteristics and inundation regimes is limited. We integrated field measurements, laboratory incubations, and model simulations to improve mechanistic understanding of oxygen consumption dynamics in coastal soils. Continuous in situ monitoring unexpectedly revealed that flooding caused temporary spikes in subsurface dissolved oxygen followed by rapid consumption in the wetlands. To further investigate these mechanisms in a controlled setting, we performed laboratory incubations using surface and subsurface soils from a TAI gradient (defined here as upland forest to transitional forest to wetland) in Western Lake Erie to measure oxygen consumption rates in TAI soils during flood events. In our experiments, wetland soils reached anoxia the fastest, in ∼ 9 h on average, whereas upland soils turned anoxic in ∼ 18 h. Subsurface upland soils did not turn anoxic even after two weeks of saturation in the lab, and their oxygen consumption patterns suggested carbon and/or nutrient limitation. These results are consistent with in-situ groundwater redox and oxygen measurements in the field, where wetland soils exhibited the highest rates of oxygen consumption along the TAI. Model simulations of oxygen consumption suggested that oxygen consumption had stronger abiotic controls in wetland soils but stronger biotic controls in upland soils, providing a useful framework for future incubation experiments. Microbial activity is a strong driver of oxygen consumption in TAI soils, although it is constrained by the availability of dissolved carbon in subsurface soils.

KW - Anoxia

KW - Groundwater

KW - Model-experiment integration

KW - Soil

KW - Wetlands

UR - https://www.scopus.com/pages/publications/85187961647

U2 - 10.1016/j.geoderma.2024.116854

DO - 10.1016/j.geoderma.2024.116854

M3 - Article

AN - SCOPUS:85187961647

SN - 0016-7061

VL - 444

JO - Geoderma

JF - Geoderma

M1 - 116854

ER -

Time to anoxia: Observations and predictions of oxygen drawdown following coastal flood events

Abstract

Funding

Keywords

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