Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra

Institut for Geovidenskab og Naturforvaltning

Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Standard

Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra. / Xu, Wenyi; Elberling, Bo; Ambus, Per Lennart.

I: Soil Biology & Biochemistry, Bind 170, 108699, 2022.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Harvard

Xu, W, Elberling, B & Ambus, PL 2022, 'Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra', Soil Biology & Biochemistry, bind 170, 108699. https://doi.org/10.1016/j.soilbio.2022.108699

APA

Xu, W., Elberling, B., & Ambus, P. L. (2022). Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra. Soil Biology & Biochemistry, 170, [108699]. https://doi.org/10.1016/j.soilbio.2022.108699

Vancouver

Xu W, Elberling B, Ambus PL. Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra. Soil Biology & Biochemistry. 2022;170. 108699. https://doi.org/10.1016/j.soilbio.2022.108699

Author

Xu, Wenyi ; Elberling, Bo ; Ambus, Per Lennart. / Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra. I: Soil Biology & Biochemistry. 2022 ; Bind 170.

Bibtex

@article{dadea2c188234ccbb58421a99c63f1a0,

title = "Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra",

abstract = "In recent years, wildfire frequency and severity has increased in the Arctic tundra regions due to climate change. Pyrogenic organic matter (PyOM) is a product of incomplete combustion of biomass containing nutrients such as nitrogen (N), and is expected to affect ecosystem N cycling during a post-fire recovery period. We investigated effects of fire on soil biogeochemical cycles with a focus on pyrogenic N turnover over two subsequent growing seasons, combined with and without summer warming, in an Arctic heath tundra, West Greenland. The summer warming was achieved by deployment of open top chambers (OTCs). We simulated an in situ tundra fire by removing vegetation and litter, and scorching/heating soil surface followed by the addition of N-15-labelled PyOM (derived from aboveground biomass and litter) to the soil surface in plots with and without summer warming. A darker surface after the simulated fire resulted in an increase of 1.3 degrees C in soil temperature at 5-cm depth over the growing seasons. The fire also caused a nine-fold increase in soil NH4+-N and three-fold increase in soil NO3--N concentrations at 7-cm depth after two years. Tracing the fate of N-15-labelled PyOM, 21 days after its application, showed low N-15 recovery in microbial biomass (0.4%) and total dissolved N (TDN) pools (0.01%). Microbial and root N-15 recovery increased two-fold and 15-fold after one year, respectively, and TDN N-15 recovery increased two-fold after two years, suggesting that relatively recalcitrant N of PyOM can be partly transformed into plantavailable forms over time. Root and TDN N-15 recovery was also significantly higher after two years of summer warming than under ambient temperature conditions, suggesting that summer warming can enhance availability of PyOM-N for recovering plants after the fire. Hence, we conclude that fire-induced PyOM can act as an N source for plant recovery in this Arctic tundra ecosystem for years after the fire, and this N source will become increasingly important in a future warmer climate.",

keywords = "Tundra fire, Summer warming, Nitrogen-15-labelled pyrogenic organic matter (N-15-PyOM), Microbial biomass, Plant-available nitrogen (N), Nitrous oxide, SOIL MICROBES, BLACK CARBON, FOREST, DEGRADATION, DYNAMICS, DECOMPOSITION, SUMMER, WATER, COMPETITION, EFFICIENCY",

author = "Wenyi Xu and Bo Elberling and Ambus, {Per Lennart}",

note = "CENPERMOA[2022]",

year = "2022",

doi = "10.1016/j.soilbio.2022.108699",

language = "English",

volume = "170",

journal = "Soil Biology & Biochemistry",

issn = "0038-0717",

publisher = "Pergamon Press",

}

RIS

TY - JOUR

T1 - Pyrogenic organic matter as a nitrogen source to microbes and plants following fire in an Arctic heath tundra

AU - Xu, Wenyi

AU - Elberling, Bo

AU - Ambus, Per Lennart

N1 - CENPERMOA[2022]

PY - 2022

Y1 - 2022

N2 - In recent years, wildfire frequency and severity has increased in the Arctic tundra regions due to climate change. Pyrogenic organic matter (PyOM) is a product of incomplete combustion of biomass containing nutrients such as nitrogen (N), and is expected to affect ecosystem N cycling during a post-fire recovery period. We investigated effects of fire on soil biogeochemical cycles with a focus on pyrogenic N turnover over two subsequent growing seasons, combined with and without summer warming, in an Arctic heath tundra, West Greenland. The summer warming was achieved by deployment of open top chambers (OTCs). We simulated an in situ tundra fire by removing vegetation and litter, and scorching/heating soil surface followed by the addition of N-15-labelled PyOM (derived from aboveground biomass and litter) to the soil surface in plots with and without summer warming. A darker surface after the simulated fire resulted in an increase of 1.3 degrees C in soil temperature at 5-cm depth over the growing seasons. The fire also caused a nine-fold increase in soil NH4+-N and three-fold increase in soil NO3--N concentrations at 7-cm depth after two years. Tracing the fate of N-15-labelled PyOM, 21 days after its application, showed low N-15 recovery in microbial biomass (0.4%) and total dissolved N (TDN) pools (0.01%). Microbial and root N-15 recovery increased two-fold and 15-fold after one year, respectively, and TDN N-15 recovery increased two-fold after two years, suggesting that relatively recalcitrant N of PyOM can be partly transformed into plantavailable forms over time. Root and TDN N-15 recovery was also significantly higher after two years of summer warming than under ambient temperature conditions, suggesting that summer warming can enhance availability of PyOM-N for recovering plants after the fire. Hence, we conclude that fire-induced PyOM can act as an N source for plant recovery in this Arctic tundra ecosystem for years after the fire, and this N source will become increasingly important in a future warmer climate.

AB - In recent years, wildfire frequency and severity has increased in the Arctic tundra regions due to climate change. Pyrogenic organic matter (PyOM) is a product of incomplete combustion of biomass containing nutrients such as nitrogen (N), and is expected to affect ecosystem N cycling during a post-fire recovery period. We investigated effects of fire on soil biogeochemical cycles with a focus on pyrogenic N turnover over two subsequent growing seasons, combined with and without summer warming, in an Arctic heath tundra, West Greenland. The summer warming was achieved by deployment of open top chambers (OTCs). We simulated an in situ tundra fire by removing vegetation and litter, and scorching/heating soil surface followed by the addition of N-15-labelled PyOM (derived from aboveground biomass and litter) to the soil surface in plots with and without summer warming. A darker surface after the simulated fire resulted in an increase of 1.3 degrees C in soil temperature at 5-cm depth over the growing seasons. The fire also caused a nine-fold increase in soil NH4+-N and three-fold increase in soil NO3--N concentrations at 7-cm depth after two years. Tracing the fate of N-15-labelled PyOM, 21 days after its application, showed low N-15 recovery in microbial biomass (0.4%) and total dissolved N (TDN) pools (0.01%). Microbial and root N-15 recovery increased two-fold and 15-fold after one year, respectively, and TDN N-15 recovery increased two-fold after two years, suggesting that relatively recalcitrant N of PyOM can be partly transformed into plantavailable forms over time. Root and TDN N-15 recovery was also significantly higher after two years of summer warming than under ambient temperature conditions, suggesting that summer warming can enhance availability of PyOM-N for recovering plants after the fire. Hence, we conclude that fire-induced PyOM can act as an N source for plant recovery in this Arctic tundra ecosystem for years after the fire, and this N source will become increasingly important in a future warmer climate.

KW - Tundra fire

KW - Summer warming

KW - Nitrogen-15-labelled pyrogenic organic matter (N-15-PyOM)

KW - Microbial biomass

KW - Plant-available nitrogen (N)

KW - Nitrous oxide

KW - SOIL MICROBES

KW - BLACK CARBON

KW - FOREST

KW - DEGRADATION

KW - DYNAMICS

KW - DECOMPOSITION

KW - SUMMER

KW - WATER

KW - COMPETITION

KW - EFFICIENCY

U2 - 10.1016/j.soilbio.2022.108699

DO - 10.1016/j.soilbio.2022.108699

M3 - Journal article

VL - 170

JO - Soil Biology & Biochemistry

JF - Soil Biology & Biochemistry

SN - 0038-0717

M1 - 108699

ER -

ID: 316556801