Nitrogen immobilization could link extreme winter warming events to Arctic browning

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Nitrogen immobilization could link extreme winter warming events to Arctic browning. / Rasmussen, Laura Helene; Danielsen, Birgitte Kortegaard; Elberling, Bo; Ambus, Per; Björkman, Mats P.; Rinnan, Riikka; Andresen, Louise C.

In: Soil Biology and Biochemistry, Vol. 191, 109319, 2024.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Rasmussen, LH, Danielsen, BK, Elberling, B, Ambus, P, Björkman, MP, Rinnan, R & Andresen, LC 2024, 'Nitrogen immobilization could link extreme winter warming events to Arctic browning', Soil Biology and Biochemistry, vol. 191, 109319. https://doi.org/10.1016/j.soilbio.2024.109319

APA

Rasmussen, L. H., Danielsen, B. K., Elberling, B., Ambus, P., Björkman, M. P., Rinnan, R., & Andresen, L. C. (2024). Nitrogen immobilization could link extreme winter warming events to Arctic browning. Soil Biology and Biochemistry, 191, [109319]. https://doi.org/10.1016/j.soilbio.2024.109319

Vancouver

Rasmussen LH, Danielsen BK, Elberling B, Ambus P, Björkman MP, Rinnan R et al. Nitrogen immobilization could link extreme winter warming events to Arctic browning. Soil Biology and Biochemistry. 2024;191. 109319. https://doi.org/10.1016/j.soilbio.2024.109319

Author

Rasmussen, Laura Helene ; Danielsen, Birgitte Kortegaard ; Elberling, Bo ; Ambus, Per ; Björkman, Mats P. ; Rinnan, Riikka ; Andresen, Louise C. / Nitrogen immobilization could link extreme winter warming events to Arctic browning. In: Soil Biology and Biochemistry. 2024 ; Vol. 191.

Bibtex

@article{7cd8ccfce99d4217b7c1d9e908776728,
title = "Nitrogen immobilization could link extreme winter warming events to Arctic browning",
abstract = "Arctic extreme winter warming events (WW events) have increased in frequency with climate change. WW events have been linked to damaged tundra vegetation (“Arctic browning”), but the mechanisms that link episodic winter thaw to plant damage in summer are not fully understood. We suggest that one mechanism is microbial N immobilization during the WW event, which leads to a smaller release of winter-mineralized N in spring and therefore more N limitation for vegetation in summer. We tested this hypothesis in a Western Greenlandic Low arctic tundra, where we experimentally simulated a 6 day field-scale extreme WW event and 1) used stable isotopes to trace the movement of N as a consequence of the WW event, 2) measured the effect of a WW event on spring N release in top soils in the laboratory, and 3) measured the carry-over effect on summer aboveground vegetation C/N ratio in tundra subject to a WW event. Our results show that soil mineral N released by a WW event followed by soil thaw is taken up by microbes and stored in the soil, whereas vascular plants acquired almost none, and significant amounts were lost to leaching and gaseous emissions. As soils thawed in spring, we saw weak but not significant evidence (P = 0.067) for a larger N release over the first month of spring thaw in Control soils compared to WW event soils, although not significantly. A weak signal (P = 0.07) linked WW event treatment to higher summer C/N ratios in evergreen shrubs, whereas deciduous shrubs were not affected. We conclude that our results did not show significant evidence for WW events causing Arctic browning via N immobilization and summer N limitation, but that we had indications (P < 0.1) which merits further testing of the theory in various tundra types and with repeated WW events. Evergreen shrubs could be especially sensitive to winter N immobilization, with implications for future vegetation community composition and tundra C storage.",
keywords = "Climate change, Evergreen shrub, Greenland, Mesic tundra, Nitrogen cycling",
author = "Rasmussen, {Laura Helene} and Danielsen, {Birgitte Kortegaard} and Bo Elberling and Per Ambus and Bj{\"o}rkman, {Mats P.} and Riikka Rinnan and Andresen, {Louise C.}",
note = "Publisher Copyright: {\textcopyright} 2024 The Authors",
year = "2024",
doi = "10.1016/j.soilbio.2024.109319",
language = "English",
volume = "191",
journal = "Soil Biology & Biochemistry",
issn = "0038-0717",
publisher = "Pergamon Press",

}

RIS

TY - JOUR

T1 - Nitrogen immobilization could link extreme winter warming events to Arctic browning

AU - Rasmussen, Laura Helene

AU - Danielsen, Birgitte Kortegaard

AU - Elberling, Bo

AU - Ambus, Per

AU - Björkman, Mats P.

AU - Rinnan, Riikka

AU - Andresen, Louise C.

N1 - Publisher Copyright: © 2024 The Authors

PY - 2024

Y1 - 2024

N2 - Arctic extreme winter warming events (WW events) have increased in frequency with climate change. WW events have been linked to damaged tundra vegetation (“Arctic browning”), but the mechanisms that link episodic winter thaw to plant damage in summer are not fully understood. We suggest that one mechanism is microbial N immobilization during the WW event, which leads to a smaller release of winter-mineralized N in spring and therefore more N limitation for vegetation in summer. We tested this hypothesis in a Western Greenlandic Low arctic tundra, where we experimentally simulated a 6 day field-scale extreme WW event and 1) used stable isotopes to trace the movement of N as a consequence of the WW event, 2) measured the effect of a WW event on spring N release in top soils in the laboratory, and 3) measured the carry-over effect on summer aboveground vegetation C/N ratio in tundra subject to a WW event. Our results show that soil mineral N released by a WW event followed by soil thaw is taken up by microbes and stored in the soil, whereas vascular plants acquired almost none, and significant amounts were lost to leaching and gaseous emissions. As soils thawed in spring, we saw weak but not significant evidence (P = 0.067) for a larger N release over the first month of spring thaw in Control soils compared to WW event soils, although not significantly. A weak signal (P = 0.07) linked WW event treatment to higher summer C/N ratios in evergreen shrubs, whereas deciduous shrubs were not affected. We conclude that our results did not show significant evidence for WW events causing Arctic browning via N immobilization and summer N limitation, but that we had indications (P < 0.1) which merits further testing of the theory in various tundra types and with repeated WW events. Evergreen shrubs could be especially sensitive to winter N immobilization, with implications for future vegetation community composition and tundra C storage.

AB - Arctic extreme winter warming events (WW events) have increased in frequency with climate change. WW events have been linked to damaged tundra vegetation (“Arctic browning”), but the mechanisms that link episodic winter thaw to plant damage in summer are not fully understood. We suggest that one mechanism is microbial N immobilization during the WW event, which leads to a smaller release of winter-mineralized N in spring and therefore more N limitation for vegetation in summer. We tested this hypothesis in a Western Greenlandic Low arctic tundra, where we experimentally simulated a 6 day field-scale extreme WW event and 1) used stable isotopes to trace the movement of N as a consequence of the WW event, 2) measured the effect of a WW event on spring N release in top soils in the laboratory, and 3) measured the carry-over effect on summer aboveground vegetation C/N ratio in tundra subject to a WW event. Our results show that soil mineral N released by a WW event followed by soil thaw is taken up by microbes and stored in the soil, whereas vascular plants acquired almost none, and significant amounts were lost to leaching and gaseous emissions. As soils thawed in spring, we saw weak but not significant evidence (P = 0.067) for a larger N release over the first month of spring thaw in Control soils compared to WW event soils, although not significantly. A weak signal (P = 0.07) linked WW event treatment to higher summer C/N ratios in evergreen shrubs, whereas deciduous shrubs were not affected. We conclude that our results did not show significant evidence for WW events causing Arctic browning via N immobilization and summer N limitation, but that we had indications (P < 0.1) which merits further testing of the theory in various tundra types and with repeated WW events. Evergreen shrubs could be especially sensitive to winter N immobilization, with implications for future vegetation community composition and tundra C storage.

KW - Climate change

KW - Evergreen shrub

KW - Greenland

KW - Mesic tundra

KW - Nitrogen cycling

U2 - 10.1016/j.soilbio.2024.109319

DO - 10.1016/j.soilbio.2024.109319

M3 - Journal article

AN - SCOPUS:85184021808

VL - 191

JO - Soil Biology & Biochemistry

JF - Soil Biology & Biochemistry

SN - 0038-0717

M1 - 109319

ER -

ID: 382436645