Nitrogen (May 2022)

Increased Arctic NO<sub>3</sub><sup>−</sup> Availability as a Hydrogeomorphic Consequence of Permafrost Degradation and Landscape Drying

  • Carli A. Arendt,
  • Jeffrey M. Heikoop,
  • Brent D. Newman,
  • Cathy J. Wilson,
  • Haruko Wainwright,
  • Jitendra Kumar,
  • Christian G. Andersen,
  • Nathan A. Wales,
  • Baptiste Dafflon,
  • Jessica Cherry,
  • Stan D. Wullschleger

DOI
https://doi.org/10.3390/nitrogen3020021
Journal volume & issue
Vol. 3, no. 2
pp. 314 – 332

Abstract

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Climate-driven permafrost thaw alters the strongly coupled carbon and nitrogen cycles within the Arctic tundra, influencing the availability of limiting nutrients including nitrate (NO3−). Researchers have identified two primary mechanisms that increase nitrogen and NO3− availability within permafrost soils: (1) the ‘frozen feast’, where previously frozen organic material becomes available as it thaws, and (2) ‘shrubification’, where expansion of nitrogen-fixing shrubs promotes increased soil nitrogen. Through the synthesis of original and previously published observational data, and the application of multiple geospatial approaches, this study investigates and highlights a third mechanism that increases NO3− availability: the hydrogeomorphic evolution of polygonal permafrost landscapes. Permafrost thaw drives changes in microtopography, increasing the drainage of topographic highs, thus increasing oxic conditions that promote NO3− production and accumulation. We extrapolate relationships between NO3− and soil moisture in elevated topographic features within our study area and the broader Alaskan Coastal Plain and investigate potential changes in NO3− availability in response to possible hydrogeomorphic evolution scenarios of permafrost landscapes. These approximations indicate that such changes could increase Arctic tundra NO3− availability by ~250–1000%. Thus, hydrogeomorphic changes that accompany continued permafrost degradation in polygonal permafrost landscapes will substantially increase soil pore water NO3− availability and boost future fertilization and productivity in the Arctic.

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