Fire increases soil nitrogen retention and alters nitrogen uptake patterns among dominant shrub species in an Arctic dry heath tundra

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Fire increases soil nitrogen retention and alters nitrogen uptake patterns among dominant shrub species in an Arctic dry heath tundra. / Xu, Wenyi; Elberling, Bo; Ambus, Per Lennart.

In: Science of the Total Environment, Vol. 807, No. Part 3, 150990, 2021.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Xu, W, Elberling, B & Ambus, PL 2021, 'Fire increases soil nitrogen retention and alters nitrogen uptake patterns among dominant shrub species in an Arctic dry heath tundra', Science of the Total Environment, vol. 807, no. Part 3, 150990. https://doi.org/10.1016/j.scitotenv.2021.150990

APA

Xu, W., Elberling, B., & Ambus, P. L. (2021). Fire increases soil nitrogen retention and alters nitrogen uptake patterns among dominant shrub species in an Arctic dry heath tundra. Science of the Total Environment, 807(Part 3), [150990]. https://doi.org/10.1016/j.scitotenv.2021.150990

Vancouver

Xu W, Elberling B, Ambus PL. Fire increases soil nitrogen retention and alters nitrogen uptake patterns among dominant shrub species in an Arctic dry heath tundra. Science of the Total Environment. 2021;807(Part 3). 150990. https://doi.org/10.1016/j.scitotenv.2021.150990

Author

Xu, Wenyi ; Elberling, Bo ; Ambus, Per Lennart. / Fire increases soil nitrogen retention and alters nitrogen uptake patterns among dominant shrub species in an Arctic dry heath tundra. In: Science of the Total Environment. 2021 ; Vol. 807, No. Part 3.

Bibtex

@article{ebf9f001aedb478cb36e1ab9c01b636a,
title = "Fire increases soil nitrogen retention and alters nitrogen uptake patterns among dominant shrub species in an Arctic dry heath tundra",
abstract = "Climate change increases the frequency and severity of fire in the Arctic tundra regions. We assessed effects of fire in combination with summer warming on soil biogeochemical N- and P cycles with a focus on mineral N over two years following an experimental fire in a dry heath tundra, West Greenland. We applied stable isotopes (15NH4+-N and 15NO3−-N) to trace the post-fire mineral N pools. The partitioning of 15N in the bulk soils, soil dissolved organic N (TDN), microbes and plants (roots and leaves) was established. The fire tended to increase microbial P pools by four-fold at both one and two years after the fire. Two years after the fire, the bulk soil 15N recovery has decreased to 10.4% in unburned plots while relatively high recovery was maintained (30%) in burned plots, suggesting an increase in soil N retention after the fire. The contribution of microbial 15N recovery to bulk soil 15N recovery increased from 11.2% at 21 days to 31.5% two years after the fire, suggesting that higher post-fire N retention was due largely to the increased incorporation of N into microbial biomass. Fire also increased 15N recovery in bulk roots after one and two years, but only under summer warming. This suggests that higher retention of post-fire N can strongly increase the potential for N uptake of recovering plants under a future warmer climate. There was significantly lower 15N enrichment of Betula nana leaves while higher 15N enrichment of Vaccinium uliginosum leaves (after three years) in burned than control plots. This shows that fire can alter the N uptake differently among dominant shrub species in this tundra ecosystem, and implies that wildfires may change plant species composition in the longer term.",
keywords = "N tracing, Microbial biomass phosphorus, Shrub cutting, Tundra fire, Warming",
author = "Wenyi Xu and Bo Elberling and Ambus, {Per Lennart}",
note = "CENPERMOA[2022] Publisher Copyright: {\textcopyright} 2021 The Authors",
year = "2021",
doi = "10.1016/j.scitotenv.2021.150990",
language = "English",
volume = "807",
journal = "Science of the Total Environment",
issn = "0048-9697",
publisher = "Elsevier",
number = "Part 3",

}

RIS

TY - JOUR

T1 - Fire increases soil nitrogen retention and alters nitrogen uptake patterns among dominant shrub species in an Arctic dry heath tundra

AU - Xu, Wenyi

AU - Elberling, Bo

AU - Ambus, Per Lennart

N1 - CENPERMOA[2022] Publisher Copyright: © 2021 The Authors

PY - 2021

Y1 - 2021

N2 - Climate change increases the frequency and severity of fire in the Arctic tundra regions. We assessed effects of fire in combination with summer warming on soil biogeochemical N- and P cycles with a focus on mineral N over two years following an experimental fire in a dry heath tundra, West Greenland. We applied stable isotopes (15NH4+-N and 15NO3−-N) to trace the post-fire mineral N pools. The partitioning of 15N in the bulk soils, soil dissolved organic N (TDN), microbes and plants (roots and leaves) was established. The fire tended to increase microbial P pools by four-fold at both one and two years after the fire. Two years after the fire, the bulk soil 15N recovery has decreased to 10.4% in unburned plots while relatively high recovery was maintained (30%) in burned plots, suggesting an increase in soil N retention after the fire. The contribution of microbial 15N recovery to bulk soil 15N recovery increased from 11.2% at 21 days to 31.5% two years after the fire, suggesting that higher post-fire N retention was due largely to the increased incorporation of N into microbial biomass. Fire also increased 15N recovery in bulk roots after one and two years, but only under summer warming. This suggests that higher retention of post-fire N can strongly increase the potential for N uptake of recovering plants under a future warmer climate. There was significantly lower 15N enrichment of Betula nana leaves while higher 15N enrichment of Vaccinium uliginosum leaves (after three years) in burned than control plots. This shows that fire can alter the N uptake differently among dominant shrub species in this tundra ecosystem, and implies that wildfires may change plant species composition in the longer term.

AB - Climate change increases the frequency and severity of fire in the Arctic tundra regions. We assessed effects of fire in combination with summer warming on soil biogeochemical N- and P cycles with a focus on mineral N over two years following an experimental fire in a dry heath tundra, West Greenland. We applied stable isotopes (15NH4+-N and 15NO3−-N) to trace the post-fire mineral N pools. The partitioning of 15N in the bulk soils, soil dissolved organic N (TDN), microbes and plants (roots and leaves) was established. The fire tended to increase microbial P pools by four-fold at both one and two years after the fire. Two years after the fire, the bulk soil 15N recovery has decreased to 10.4% in unburned plots while relatively high recovery was maintained (30%) in burned plots, suggesting an increase in soil N retention after the fire. The contribution of microbial 15N recovery to bulk soil 15N recovery increased from 11.2% at 21 days to 31.5% two years after the fire, suggesting that higher post-fire N retention was due largely to the increased incorporation of N into microbial biomass. Fire also increased 15N recovery in bulk roots after one and two years, but only under summer warming. This suggests that higher retention of post-fire N can strongly increase the potential for N uptake of recovering plants under a future warmer climate. There was significantly lower 15N enrichment of Betula nana leaves while higher 15N enrichment of Vaccinium uliginosum leaves (after three years) in burned than control plots. This shows that fire can alter the N uptake differently among dominant shrub species in this tundra ecosystem, and implies that wildfires may change plant species composition in the longer term.

KW - N tracing

KW - Microbial biomass phosphorus

KW - Shrub cutting

KW - Tundra fire

KW - Warming

U2 - 10.1016/j.scitotenv.2021.150990

DO - 10.1016/j.scitotenv.2021.150990

M3 - Journal article

C2 - 34656575

AN - SCOPUS:85117384460

VL - 807

JO - Science of the Total Environment

JF - Science of the Total Environment

SN - 0048-9697

IS - Part 3

M1 - 150990

ER -

ID: 285313405