High nitrate variability on an Alaskan permafrost hillslope dominated by alder shrubs

Rachael E. McCaully; Carli A. Arendt; Brent D. Newman; Verity G. Salmon; Jeffrey M. Heikoop; Cathy J. Wilson; Sanna Sevanto; Nathan A. Wales; George B. Perkins; Oana C. Marina; Stan D. Wullschleger

doi:10.5194/tc-16-1889-2022

High nitrate variability on an Alaskan permafrost hillslope dominated by alder shrubs

Rachael E. McCaully, Carli A. Arendt, Brent D. Newman, Verity G. Salmon, Jeffrey M. Heikoop, Cathy J. Wilson, Sanna Sevanto, Nathan A. Wales, George B. Perkins, Oana C. Marina, Stan D. Wullschleger

Plant-Soil Interactions

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

In Arctic ecosystems, increasing temperatures are driving the expansion of nitrogen (N) fixing shrubs across tundra landscapes. The implications of this expansion to the biogeochemistry of Arctic ecosystems are of critical importance and more work is needed to better understand the form, availability, and transportation potential of N from these shrubs across a variety of Arctic landscapes. To gain insights into the processes controlling N within a permafrost hillslope system, the spatiotemporal variability of nitrate (NO3-) and its environmental controls were investigated at an alder (Alnus viridis spp. fruticosa) dominated permafrost tundra landscape in the Seward Peninsula, Alaska, USA. Soil pore water was collected from locations within alder shrubland growing along a well-drained hillslope and was compared to soil pore water collected from locations outside (upslope, downslope, and between) the alder shrubland. Soil pore water collected within alder shrubland had an average NO3-N (nitrogen from nitrate) concentration of 4.27±8.02?€¯mg?€¯L-1 and differed significantly from locations outside alder shrubland (0.23±0.83?€¯mg?€¯L-1; p<0.05). Temporal variation in NO3-N within and downslope of alder shrubland co-occurred with precipitation events where NO3- that accumulated in the soil was likely flushed downslope during rainfall. These findings have important implications for nutrient availability and mobility in N-limited permafrost systems that are experiencing shrub expansion in response to a warming Arctic.

Original language	English
Pages (from-to)	1889-1901
Number of pages	13
Journal	Cryosphere
Volume	16
Issue number	5
DOIs	https://doi.org/10.5194/tc-16-1889-2022
State	Published - May 19 2022

Funding

Copyright statement. This manuscript has been authored by UT-Battelle, LLC under Contract No. DE-AC05-00OR22725 with the U.S. Department of Energy. The United States Government retains and the publisher, by accepting the article for publication, acknowledges that the United States Government retains a non-exclusive, paid-up, irrevocable, world-wide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States Government purposes. The Department of Energy will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan (http://energy.gov/downloads/doe-public-access-plan). This research has been supported by the United States Department of Energy (DOE) Office of Science, Biological and Environmental Research program

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title = "High nitrate variability on an Alaskan permafrost hillslope dominated by alder shrubs",

abstract = "In Arctic ecosystems, increasing temperatures are driving the expansion of nitrogen (N) fixing shrubs across tundra landscapes. The implications of this expansion to the biogeochemistry of Arctic ecosystems are of critical importance and more work is needed to better understand the form, availability, and transportation potential of N from these shrubs across a variety of Arctic landscapes. To gain insights into the processes controlling N within a permafrost hillslope system, the spatiotemporal variability of nitrate (NO3-) and its environmental controls were investigated at an alder (Alnus viridis spp. fruticosa) dominated permafrost tundra landscape in the Seward Peninsula, Alaska, USA. Soil pore water was collected from locations within alder shrubland growing along a well-drained hillslope and was compared to soil pore water collected from locations outside (upslope, downslope, and between) the alder shrubland. Soil pore water collected within alder shrubland had an average NO3-N (nitrogen from nitrate) concentration of 4.27±8.02?€¯mg?€¯L-1 and differed significantly from locations outside alder shrubland (0.23±0.83?€¯mg?€¯L-1; p<0.05). Temporal variation in NO3-N within and downslope of alder shrubland co-occurred with precipitation events where NO3- that accumulated in the soil was likely flushed downslope during rainfall. These findings have important implications for nutrient availability and mobility in N-limited permafrost systems that are experiencing shrub expansion in response to a warming Arctic.",

author = "McCaully, {Rachael E.} and Arendt, {Carli A.} and Newman, {Brent D.} and Salmon, {Verity G.} and Heikoop, {Jeffrey M.} and Wilson, {Cathy J.} and Sanna Sevanto and Wales, {Nathan A.} and Perkins, {George B.} and Marina, {Oana C.} and Wullschleger, {Stan D.}",

note = "Publisher Copyright: {\textcopyright} 2022 Rachael E. McCaully et al.",

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doi = "10.5194/tc-16-1889-2022",

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T1 - High nitrate variability on an Alaskan permafrost hillslope dominated by alder shrubs

AU - McCaully, Rachael E.

AU - Arendt, Carli A.

AU - Newman, Brent D.

AU - Salmon, Verity G.

AU - Heikoop, Jeffrey M.

AU - Wilson, Cathy J.

AU - Sevanto, Sanna

AU - Wales, Nathan A.

AU - Perkins, George B.

AU - Marina, Oana C.

AU - Wullschleger, Stan D.

PY - 2022/5/19

Y1 - 2022/5/19

N2 - In Arctic ecosystems, increasing temperatures are driving the expansion of nitrogen (N) fixing shrubs across tundra landscapes. The implications of this expansion to the biogeochemistry of Arctic ecosystems are of critical importance and more work is needed to better understand the form, availability, and transportation potential of N from these shrubs across a variety of Arctic landscapes. To gain insights into the processes controlling N within a permafrost hillslope system, the spatiotemporal variability of nitrate (NO3-) and its environmental controls were investigated at an alder (Alnus viridis spp. fruticosa) dominated permafrost tundra landscape in the Seward Peninsula, Alaska, USA. Soil pore water was collected from locations within alder shrubland growing along a well-drained hillslope and was compared to soil pore water collected from locations outside (upslope, downslope, and between) the alder shrubland. Soil pore water collected within alder shrubland had an average NO3-N (nitrogen from nitrate) concentration of 4.27±8.02?€¯mg?€¯L-1 and differed significantly from locations outside alder shrubland (0.23±0.83?€¯mg?€¯L-1; p<0.05). Temporal variation in NO3-N within and downslope of alder shrubland co-occurred with precipitation events where NO3- that accumulated in the soil was likely flushed downslope during rainfall. These findings have important implications for nutrient availability and mobility in N-limited permafrost systems that are experiencing shrub expansion in response to a warming Arctic.

AB - In Arctic ecosystems, increasing temperatures are driving the expansion of nitrogen (N) fixing shrubs across tundra landscapes. The implications of this expansion to the biogeochemistry of Arctic ecosystems are of critical importance and more work is needed to better understand the form, availability, and transportation potential of N from these shrubs across a variety of Arctic landscapes. To gain insights into the processes controlling N within a permafrost hillslope system, the spatiotemporal variability of nitrate (NO3-) and its environmental controls were investigated at an alder (Alnus viridis spp. fruticosa) dominated permafrost tundra landscape in the Seward Peninsula, Alaska, USA. Soil pore water was collected from locations within alder shrubland growing along a well-drained hillslope and was compared to soil pore water collected from locations outside (upslope, downslope, and between) the alder shrubland. Soil pore water collected within alder shrubland had an average NO3-N (nitrogen from nitrate) concentration of 4.27±8.02?€¯mg?€¯L-1 and differed significantly from locations outside alder shrubland (0.23±0.83?€¯mg?€¯L-1; p<0.05). Temporal variation in NO3-N within and downslope of alder shrubland co-occurred with precipitation events where NO3- that accumulated in the soil was likely flushed downslope during rainfall. These findings have important implications for nutrient availability and mobility in N-limited permafrost systems that are experiencing shrub expansion in response to a warming Arctic.

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AN - SCOPUS:85131745063

SN - 1994-0416

VL - 16

SP - 1889

EP - 1901

JO - Cryosphere

JF - Cryosphere

IS - 5

ER -

High nitrate variability on an Alaskan permafrost hillslope dominated by alder shrubs

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