Rapid Permafrost Thaw Removes Nitrogen Limitation and Rises the Potential for N 2 O Emissions

Ice–rich Pleistocene permafrost deposits (Yedoma) store large amounts of nitrogen (N) and are susceptible to rapid thaw. In this study, we assess whether eroding Yedoma deposits are potential sources of N and gaseous carbon (C) losses. Therefore, we determined aerobic net ammonification and nitrific...

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Bibliographic Details
Published in:Nitrogen
Main Authors: Rica Wegner, Claudia Fiencke, Christian Knoblauch, Lewis Sauerland, Christian Beer
Format: Article in Journal/Newspaper
Language:English
Published: MDPI AG 2022
Subjects:
ammonification
nitrification
N 2 O
denitrification
thermoerosion
retrogressive thaw slumps
Ecology
QH540-549.5
Ice
lena river
permafrost
Siberia
Online Access:https://doi.org/10.3390/nitrogen3040040
https://doaj.org/article/632b4f48752b4b4ea4fce78934b52aab
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Summary:Ice–rich Pleistocene permafrost deposits (Yedoma) store large amounts of nitrogen (N) and are susceptible to rapid thaw. In this study, we assess whether eroding Yedoma deposits are potential sources of N and gaseous carbon (C) losses. Therefore, we determined aerobic net ammonification and nitrification, as well as anaerobic production of nitrous oxide (N 2 O), carbon dioxide (CO 2 ), and methane (CH 4 ) in laboratory incubations. Samples were collected from non-vegetated and revegetated slump floor (SF) and thaw mound (TM) soils of a retrogressive thaw slump in the Lena River Delta of Eastern Siberia. We found high nitrate concentrations (up to 110 µg N (g DW) −1 ) within the growing season, a faster transformation of organic N to nitrate, and high N 2 O production (up to 217 ng N 2 O-N (g DW) −1 day −1 ) in revegetated thaw mounds. The slump floor was low in nitrate and did not produce N 2 O under anaerobic conditions, but produced the most CO 2 (up to 7 µg CO 2 -C (g DW) −1 day −1 ) and CH 4 (up to 65 ng CH 4 -C (g DW) −1 day −1 ). Nitrate additions showed that denitrification was substrate limited in the slump floor. Nitrate limitation was rather caused by field conditions (moisture, pH) than by microbial functional limitation since nitrification rates were positive under laboratory conditions. Our results emphasize the relevance of considering landscape processes, geomorphology, and soil origin in order to identify hotspots of high N availability, as well as C and N losses. High N availability is likely to have an impact on carbon cycling, but to what extent needs further investigation.

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