Temperature and water-level effects on greenhouse gas fluxes from black ash (Fraxinus nigra) wetland soils in the Upper Great Lakes region, USA

Alan J.Z. Toczydlowski; Robert A. Slesak; Randall K. Kolka; Rodney T. Venterea

doi:10.1016/j.apsoil.2020.103565

Temperature and water-level effects on greenhouse gas fluxes from black ash (Fraxinus nigra) wetland soils in the Upper Great Lakes region, USA

Alan J.Z. Toczydlowski, Robert A. Slesak, Randall K. Kolka, Rodney T. Venterea

Forest Resources

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Abstract

Forested black ash (Fraxinus nigra) wetlands are an important economic, cultural, and ecological resource in the northern Great Lake States, USA, and are threatened by the invasive insect, emerald ash borer (Agrilus planipennis Fairmmaire [EAB]). These wetlands are likely to experience higher water tables and warmer temperatures if they are impacted by large-scale ash mortality and other global change factors. Therefore, it is critical to understand how temperature, hydrology, and their interaction affect greenhouse gas fluxes in black ash wetland soils. In order to predict potential ecosystem changes, we sampled and incubated intact soil cores containing either mineral or organic (peat) soils from two black ash wetlands, monitored soil oxidation-reduction potential (Eh), and measured the efflux of carbon dioxide (CO₂), methane (CH₄), and nitrous oxide (N₂O) at two water-level treatments nested in three temperature treatments, 10 °C, 15 °C, or 20 °C. The water-level treatments were either saturated or drawdown, designed to mimic wetlands impacted or not impacted by EAB. Mean CO₂ fluxes increased with increasing temperature but did not vary significantly by soil type or water-level. Peat soil had 60 to 135 times significantly greater CH₄ flux in the saturated treatment and had minimal N₂O loss across all treatments, while mineral soils had 8 to 43 times significantly greater N₂O flux in the saturated treatment, and minimal CH₄ loss across all treatments. Gas fluxes generally increased and had greater variation with increasing temperature. The drawdown treatment resulted in significantly higher Eh during unsaturated periods in both soil types, but the response was more variable in the peat soil. Our findings demonstrate potential indirect effects of EAB in black ash wetlands, with implications for ecosystem functions associated with C and N cycling.

Original language	English (US)
Article number	103565
Journal	Applied Soil Ecology
Volume	153
DOIs	https://doi.org/10.1016/j.apsoil.2020.103565
State	Published - Sep 2020

Bibliographical note

Funding Information:
This research was funded in part by the Minnesota Forest Resources Council, USDA Forest Service Northern Research Station, and the University of Minnesota Department of Forest Resources. We gratefully acknowledge Anne Gapinski, Joseph Shannon, Mitchell Slater, and David and Patricia Toczydlowski for assistance with fieldwork, and Nathan Aspelin, Douglas Brinkman, Cindy Buschena, Michael Dolan, and the USDA USFS Northern Research Station for conducting and assisting with laboratory analyses. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Funding Information:
This research was funded in part by the Minnesota Forest Resources Council, USDA Forest Service Northern Research Station , and the University of Minnesota Department of Forest Resources . We gratefully acknowledge Anne Gapinski, Joseph Shannon, Mitchell Slater, and David and Patricia Toczydlowski for assistance with fieldwork, and Nathan Aspelin, Douglas Brinkman, Cindy Buschena, Michael Dolan, and the USDA USFS Northern Research Station for conducting and assisting with laboratory analyses.

Publisher Copyright:
© 2020 Elsevier B.V.

Keywords

Emerald ash borer
Forested wetlands
Greenhouse gas fluxes
Methane
Nitrous oxide
Soil core incubation
Soil redox

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title = "Temperature and water-level effects on greenhouse gas fluxes from black ash (Fraxinus nigra) wetland soils in the Upper Great Lakes region, USA",

abstract = "Forested black ash (Fraxinus nigra) wetlands are an important economic, cultural, and ecological resource in the northern Great Lake States, USA, and are threatened by the invasive insect, emerald ash borer (Agrilus planipennis Fairmmaire [EAB]). These wetlands are likely to experience higher water tables and warmer temperatures if they are impacted by large-scale ash mortality and other global change factors. Therefore, it is critical to understand how temperature, hydrology, and their interaction affect greenhouse gas fluxes in black ash wetland soils. In order to predict potential ecosystem changes, we sampled and incubated intact soil cores containing either mineral or organic (peat) soils from two black ash wetlands, monitored soil oxidation-reduction potential (Eh), and measured the efflux of carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O) at two water-level treatments nested in three temperature treatments, 10 °C, 15 °C, or 20 °C. The water-level treatments were either saturated or drawdown, designed to mimic wetlands impacted or not impacted by EAB. Mean CO2 fluxes increased with increasing temperature but did not vary significantly by soil type or water-level. Peat soil had 60 to 135 times significantly greater CH4 flux in the saturated treatment and had minimal N2O loss across all treatments, while mineral soils had 8 to 43 times significantly greater N2O flux in the saturated treatment, and minimal CH4 loss across all treatments. Gas fluxes generally increased and had greater variation with increasing temperature. The drawdown treatment resulted in significantly higher Eh during unsaturated periods in both soil types, but the response was more variable in the peat soil. Our findings demonstrate potential indirect effects of EAB in black ash wetlands, with implications for ecosystem functions associated with C and N cycling.",

keywords = "Emerald ash borer, Forested wetlands, Greenhouse gas fluxes, Methane, Nitrous oxide, Soil core incubation, Soil redox",

author = "Toczydlowski, {Alan J.Z.} and Slesak, {Robert A.} and Kolka, {Randall K.} and Venterea, {Rodney T.}",

note = "Funding Information: This research was funded in part by the Minnesota Forest Resources Council, USDA Forest Service Northern Research Station, and the University of Minnesota Department of Forest Resources. We gratefully acknowledge Anne Gapinski, Joseph Shannon, Mitchell Slater, and David and Patricia Toczydlowski for assistance with fieldwork, and Nathan Aspelin, Douglas Brinkman, Cindy Buschena, Michael Dolan, and the USDA USFS Northern Research Station for conducting and assisting with laboratory analyses. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. Funding Information: This research was funded in part by the Minnesota Forest Resources Council, USDA Forest Service Northern Research Station , and the University of Minnesota Department of Forest Resources . We gratefully acknowledge Anne Gapinski, Joseph Shannon, Mitchell Slater, and David and Patricia Toczydlowski for assistance with fieldwork, and Nathan Aspelin, Douglas Brinkman, Cindy Buschena, Michael Dolan, and the USDA USFS Northern Research Station for conducting and assisting with laboratory analyses. Publisher Copyright: {\textcopyright} 2020 Elsevier B.V.",

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AU - Toczydlowski, Alan J.Z.

AU - Slesak, Robert A.

AU - Kolka, Randall K.

AU - Venterea, Rodney T.

N1 - Funding Information: This research was funded in part by the Minnesota Forest Resources Council, USDA Forest Service Northern Research Station, and the University of Minnesota Department of Forest Resources. We gratefully acknowledge Anne Gapinski, Joseph Shannon, Mitchell Slater, and David and Patricia Toczydlowski for assistance with fieldwork, and Nathan Aspelin, Douglas Brinkman, Cindy Buschena, Michael Dolan, and the USDA USFS Northern Research Station for conducting and assisting with laboratory analyses. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. Funding Information: This research was funded in part by the Minnesota Forest Resources Council, USDA Forest Service Northern Research Station , and the University of Minnesota Department of Forest Resources . We gratefully acknowledge Anne Gapinski, Joseph Shannon, Mitchell Slater, and David and Patricia Toczydlowski for assistance with fieldwork, and Nathan Aspelin, Douglas Brinkman, Cindy Buschena, Michael Dolan, and the USDA USFS Northern Research Station for conducting and assisting with laboratory analyses. Publisher Copyright: © 2020 Elsevier B.V.

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N2 - Forested black ash (Fraxinus nigra) wetlands are an important economic, cultural, and ecological resource in the northern Great Lake States, USA, and are threatened by the invasive insect, emerald ash borer (Agrilus planipennis Fairmmaire [EAB]). These wetlands are likely to experience higher water tables and warmer temperatures if they are impacted by large-scale ash mortality and other global change factors. Therefore, it is critical to understand how temperature, hydrology, and their interaction affect greenhouse gas fluxes in black ash wetland soils. In order to predict potential ecosystem changes, we sampled and incubated intact soil cores containing either mineral or organic (peat) soils from two black ash wetlands, monitored soil oxidation-reduction potential (Eh), and measured the efflux of carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O) at two water-level treatments nested in three temperature treatments, 10 °C, 15 °C, or 20 °C. The water-level treatments were either saturated or drawdown, designed to mimic wetlands impacted or not impacted by EAB. Mean CO2 fluxes increased with increasing temperature but did not vary significantly by soil type or water-level. Peat soil had 60 to 135 times significantly greater CH4 flux in the saturated treatment and had minimal N2O loss across all treatments, while mineral soils had 8 to 43 times significantly greater N2O flux in the saturated treatment, and minimal CH4 loss across all treatments. Gas fluxes generally increased and had greater variation with increasing temperature. The drawdown treatment resulted in significantly higher Eh during unsaturated periods in both soil types, but the response was more variable in the peat soil. Our findings demonstrate potential indirect effects of EAB in black ash wetlands, with implications for ecosystem functions associated with C and N cycling.

AB - Forested black ash (Fraxinus nigra) wetlands are an important economic, cultural, and ecological resource in the northern Great Lake States, USA, and are threatened by the invasive insect, emerald ash borer (Agrilus planipennis Fairmmaire [EAB]). These wetlands are likely to experience higher water tables and warmer temperatures if they are impacted by large-scale ash mortality and other global change factors. Therefore, it is critical to understand how temperature, hydrology, and their interaction affect greenhouse gas fluxes in black ash wetland soils. In order to predict potential ecosystem changes, we sampled and incubated intact soil cores containing either mineral or organic (peat) soils from two black ash wetlands, monitored soil oxidation-reduction potential (Eh), and measured the efflux of carbon dioxide (CO2), methane (CH4), and nitrous oxide (N2O) at two water-level treatments nested in three temperature treatments, 10 °C, 15 °C, or 20 °C. The water-level treatments were either saturated or drawdown, designed to mimic wetlands impacted or not impacted by EAB. Mean CO2 fluxes increased with increasing temperature but did not vary significantly by soil type or water-level. Peat soil had 60 to 135 times significantly greater CH4 flux in the saturated treatment and had minimal N2O loss across all treatments, while mineral soils had 8 to 43 times significantly greater N2O flux in the saturated treatment, and minimal CH4 loss across all treatments. Gas fluxes generally increased and had greater variation with increasing temperature. The drawdown treatment resulted in significantly higher Eh during unsaturated periods in both soil types, but the response was more variable in the peat soil. Our findings demonstrate potential indirect effects of EAB in black ash wetlands, with implications for ecosystem functions associated with C and N cycling.

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KW - Forested wetlands

KW - Greenhouse gas fluxes

KW - Methane

KW - Nitrous oxide

KW - Soil core incubation

KW - Soil redox

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Temperature and water-level effects on greenhouse gas fluxes from black ash (Fraxinus nigra) wetland soils in the Upper Great Lakes region, USA

Abstract

Bibliographical note

Keywords

UN SDGs

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