Forest soil and deadwood CH4 fluxes in response to warming, increased precipitation, nitrogen fertilization and biochar addition across a Norwegian spruce age-management gradient

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Forest soil and deadwood CH4 fluxes in response to warming, increased precipitation, nitrogen fertilization and biochar addition across a Norwegian spruce age-management gradient. / Johannesson, Carl-Fredrik; Larsen, Klaus Steenberg; Nordén, Jenni; Silvennoinen, Hanna.

2023. Abstract from EGU General Assembly 2023, Vienna, Austria.

Research output: Contribution to conferenceConference abstract for conferenceResearchpeer-review

Harvard

Johannesson, C-F, Larsen, KS, Nordén, J & Silvennoinen, H 2023, 'Forest soil and deadwood CH4 fluxes in response to warming, increased precipitation, nitrogen fertilization and biochar addition across a Norwegian spruce age-management gradient', EGU General Assembly 2023, Vienna, Austria, 24/04/2023 - 28/04/2023. https://doi.org/10.5194/egusphere-egu23-12510

APA

Johannesson, C-F., Larsen, K. S., Nordén, J., & Silvennoinen, H. (2023). Forest soil and deadwood CH4 fluxes in response to warming, increased precipitation, nitrogen fertilization and biochar addition across a Norwegian spruce age-management gradient. Abstract from EGU General Assembly 2023, Vienna, Austria. https://doi.org/10.5194/egusphere-egu23-12510

Vancouver

Johannesson C-F, Larsen KS, Nordén J, Silvennoinen H. Forest soil and deadwood CH4 fluxes in response to warming, increased precipitation, nitrogen fertilization and biochar addition across a Norwegian spruce age-management gradient. 2023. Abstract from EGU General Assembly 2023, Vienna, Austria. https://doi.org/10.5194/egusphere-egu23-12510

Author

Johannesson, Carl-Fredrik ; Larsen, Klaus Steenberg ; Nordén, Jenni ; Silvennoinen, Hanna. / Forest soil and deadwood CH4 fluxes in response to warming, increased precipitation, nitrogen fertilization and biochar addition across a Norwegian spruce age-management gradient. Abstract from EGU General Assembly 2023, Vienna, Austria.1 p.

Bibtex

@conference{366a547a20a64c40a2f0bc21c76f15b1,
title = "Forest soil and deadwood CH4 fluxes in response to warming, increased precipitation, nitrogen fertilization and biochar addition across a Norwegian spruce age-management gradient",
abstract = "Methane (CH4) is the second largest contributor to global warming and the importance of reducing net CH4 emissions was recently highlighted through the 2021 Global Methane Pledge. Upland forest soils are most often acting as CH4 sinks, but forest management – for example clear cutting and nitrogen (N) fertilization – carry the potential to turn CH4 sinks into CH4 sources. However, little is currently known about the underlying mechanisms and to what extent forest management affects the fluxes. Furthermore, the role of deadwood in the CH4 cycle is poorly understood and quantified but has recently received increased attention. Deadwood, like soils, can act both as a sink and a source of CH4 and the few available studies indicate that tree species, decay class and wood density are important regulators of CH4 cycling in deadwood.In the ForBioFunCtioN-project, we utilize state-of-the-art technology (LI-7810 Trace Gas Analyzer, LI-COR{\textregistered}) for in situ measurements of soil-atmosphere and deadwood-atmosphere exchange of CO2 and CH4 in an extensive climate and management manipulation experiment. Treatments include warming with open-top chambers, increased precipitation (on average 25 mm/year during the snow-free period), N fertilization (NH4NO3 150 kg/ha) and biochar addition (10 t/ha) in a total of 12 treatment combinations (n = 144) across five Norwegian spruce dominated bilberry forest sites spanning from a recent clear-cut to mature managed (80 years) and old unmanaged (140 years) stands.Here, we present the experimental setup of ForBioFunCtioN and soil and deadwood CH4 flux measurements from the snow-free period in 2021 and 2022. Initial results showed that N fertilization decreased net soil CH4 consumption and that, while at rare occasions functioning as a sink, the Norwegian spruce deadwood was almost exclusively a source of CH4. The source strength of deadwood differed substantially between sites but CH4 efflux from deadwood increased by biochar addition at all sites.",
author = "Carl-Fredrik Johannesson and Larsen, {Klaus Steenberg} and Jenni Nord{\'e}n and Hanna Silvennoinen",
year = "2023",
doi = "10.5194/egusphere-egu23-12510",
language = "English",
note = "EGU General Assembly 2023 : Vienna, Austria & Online ; Conference date: 24-04-2023 Through 28-04-2023",

}

RIS

TY - ABST

T1 - Forest soil and deadwood CH4 fluxes in response to warming, increased precipitation, nitrogen fertilization and biochar addition across a Norwegian spruce age-management gradient

AU - Johannesson, Carl-Fredrik

AU - Larsen, Klaus Steenberg

AU - Nordén, Jenni

AU - Silvennoinen, Hanna

PY - 2023

Y1 - 2023

N2 - Methane (CH4) is the second largest contributor to global warming and the importance of reducing net CH4 emissions was recently highlighted through the 2021 Global Methane Pledge. Upland forest soils are most often acting as CH4 sinks, but forest management – for example clear cutting and nitrogen (N) fertilization – carry the potential to turn CH4 sinks into CH4 sources. However, little is currently known about the underlying mechanisms and to what extent forest management affects the fluxes. Furthermore, the role of deadwood in the CH4 cycle is poorly understood and quantified but has recently received increased attention. Deadwood, like soils, can act both as a sink and a source of CH4 and the few available studies indicate that tree species, decay class and wood density are important regulators of CH4 cycling in deadwood.In the ForBioFunCtioN-project, we utilize state-of-the-art technology (LI-7810 Trace Gas Analyzer, LI-COR®) for in situ measurements of soil-atmosphere and deadwood-atmosphere exchange of CO2 and CH4 in an extensive climate and management manipulation experiment. Treatments include warming with open-top chambers, increased precipitation (on average 25 mm/year during the snow-free period), N fertilization (NH4NO3 150 kg/ha) and biochar addition (10 t/ha) in a total of 12 treatment combinations (n = 144) across five Norwegian spruce dominated bilberry forest sites spanning from a recent clear-cut to mature managed (80 years) and old unmanaged (140 years) stands.Here, we present the experimental setup of ForBioFunCtioN and soil and deadwood CH4 flux measurements from the snow-free period in 2021 and 2022. Initial results showed that N fertilization decreased net soil CH4 consumption and that, while at rare occasions functioning as a sink, the Norwegian spruce deadwood was almost exclusively a source of CH4. The source strength of deadwood differed substantially between sites but CH4 efflux from deadwood increased by biochar addition at all sites.

AB - Methane (CH4) is the second largest contributor to global warming and the importance of reducing net CH4 emissions was recently highlighted through the 2021 Global Methane Pledge. Upland forest soils are most often acting as CH4 sinks, but forest management – for example clear cutting and nitrogen (N) fertilization – carry the potential to turn CH4 sinks into CH4 sources. However, little is currently known about the underlying mechanisms and to what extent forest management affects the fluxes. Furthermore, the role of deadwood in the CH4 cycle is poorly understood and quantified but has recently received increased attention. Deadwood, like soils, can act both as a sink and a source of CH4 and the few available studies indicate that tree species, decay class and wood density are important regulators of CH4 cycling in deadwood.In the ForBioFunCtioN-project, we utilize state-of-the-art technology (LI-7810 Trace Gas Analyzer, LI-COR®) for in situ measurements of soil-atmosphere and deadwood-atmosphere exchange of CO2 and CH4 in an extensive climate and management manipulation experiment. Treatments include warming with open-top chambers, increased precipitation (on average 25 mm/year during the snow-free period), N fertilization (NH4NO3 150 kg/ha) and biochar addition (10 t/ha) in a total of 12 treatment combinations (n = 144) across five Norwegian spruce dominated bilberry forest sites spanning from a recent clear-cut to mature managed (80 years) and old unmanaged (140 years) stands.Here, we present the experimental setup of ForBioFunCtioN and soil and deadwood CH4 flux measurements from the snow-free period in 2021 and 2022. Initial results showed that N fertilization decreased net soil CH4 consumption and that, while at rare occasions functioning as a sink, the Norwegian spruce deadwood was almost exclusively a source of CH4. The source strength of deadwood differed substantially between sites but CH4 efflux from deadwood increased by biochar addition at all sites.

U2 - 10.5194/egusphere-egu23-12510

DO - 10.5194/egusphere-egu23-12510

M3 - Conference abstract for conference

T2 - EGU General Assembly 2023

Y2 - 24 April 2023 through 28 April 2023

ER -

ID: 358425857