Arctic aquatic graminoid tundra responses to nutrient availability

Unraveling the environmental controls influencing Arctic tundra productivity is paramount for advancing our predictive understanding of the causes and consequences of warming in tundra ecosystems and associated land–atmosphere feedbacks. This study focuses on aquatic emergent tundra plants, which do...

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Bibliographic Details
Published in:Biogeosciences 2021-04, Vol.18 (8), p.2649-2662
Main Authors: Andresen, Christian G, Lougheed, Vanessa L
Format: Article
Language:English
Subjects:
Aquatic environment
Aquatic plants
Arctic environments
Atmosphere
Availability
Biodegradation
Biogeochemistry
Biomass
Carbon
Coastal plains
Environmental control
Fluxes
Heterogeneity
Leaching
Leaves
Limiting factors
Methane
Mineralization
Multivariate analysis
Normalized difference vegetative index
Nutrient availability
Nutrients
Permafrost
Phosphorus
Plant growth
Polar environments
Productivity
Remote sensing
Runoff
Slumping
Soil
Soil nutrients
Soil water
Soils
Species
Taiga & tundra
Terrestrial environments
Thermokarst
Tundra
Tundra ecology
Tundras
Urban runoff
Vegetation
Vegetation index
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Summary:Unraveling the environmental controls influencing Arctic tundra productivity is paramount for advancing our predictive understanding of the causes and consequences of warming in tundra ecosystems and associated land–atmosphere feedbacks. This study focuses on aquatic emergent tundra plants, which dominate productivity and methane fluxes in the Arctic coastal plain of Alaska. In particular, we assessed how environmental nutrient availability influences production of biomass and greenness in the dominant aquatic tundra species: Arctophila fulva and Carex aquatilis. We sampled a total of 17 sites distributed across the Barrow Peninsula and Atqasuk, Alaska, following a nutrient gradient that ranged from sites with thermokarst slumping or urban runoff to sites with relatively low nutrient inputs. Employing a multivariate analysis, we explained the relationship of soil and water nutrients to plant leaf macro- and micro-nutrients. Specifically, we identified soil phosphorus as the main limiting nutrient factor given that it was the principal driver of aboveground biomass (R2=0.34, p=0.002) and normalized difference vegetation index (NDVI) (R2=0.47, p=0.002) in both species. Plot-level spectral NDVI was a good predictor of leaf P content for both species. We found long-term increases in N, P and Ca in C. aquatilis based on historical leaf nutrient data from the 1970s of our study area. This study highlights the importance of nutrient pools and mobilization between terrestrial–aquatic systems and their potential influence on productivity and land–atmosphere carbon balance. In addition, aquatic plant NDVI spectral responses to nutrients can serve as landscape hot-spot and hot-moment indicators of landscape biogeochemical heterogeneity associated with permafrost degradation, nutrient leaching and availability.
ISSN:1726-4189
1726-4170
1726-4189
DOI:10.5194/bg-18-2649-2021