Landscape variation in soil carbon stocks and respiration in an Arctic tundra ecosystem, west Greenland

The magnitude and acceleration of carbon dioxide emissions from warming Arctic tundra soil is an important part of the Region’s influence on the Earth’s climate system. We investigated the links between soil carbon stocks, soil organic matter decomposition, vegetation heterogeneity, temperature, and...

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Bibliographic Details
Published in:Arctic, Antarctic, and Alpine Research
Main Authors: Julia I. Bradley-Cook, Ross A. Virginia
Format: Article in Journal/Newspaper
Language:English
Published: Taylor & Francis Group 2018
Subjects:
soil organic carbon
landscape heterogeneity
tundra
soil respiration
soil temperature
Environmental sciences
GE1-350
Ecology
QH540-549.5
Arctic
Greenland
Kangerlussuaq
Antarctic and Alpine Research
Climate change
Tundra
Online Access:https://doi.org/10.1080/15230430.2017.1420283
https://doaj.org/article/a969ca7abeb04ae383f4b4a4f7c52efc
Description
Summary:The magnitude and acceleration of carbon dioxide emissions from warming Arctic tundra soil is an important part of the Region’s influence on the Earth’s climate system. We investigated the links between soil carbon stocks, soil organic matter decomposition, vegetation heterogeneity, temperature, and environmental sensitivities in dwarf shrub tundra near Kangerlussuaq, Greenland. We quantified carbon stocks of forty-two soil profiles using bulk density estimates based on previous studies in the region. The soil profiles were located within six vegetation types at nine study sites, distributed across an environmental gradient. We also monitored air and soil temperature and measured in situ soil respiration to quantify variation in carbon flux between vegetation types. For spatial extrapolation, we created a high-resolution land cover classification map of the study area. Aside from a single soil profile taken from a fen soil (54.55 kg C m−2; 2.13 kg N m−2), the highest carbon stocks were found in wet grassland soils (mean, 95% CI: 34.87 kg C m−2, [27.30, 44.55]). These same grassland soils also had the highest mid-growing-season soil respiration rates. Our estimation of soil carbon stocks and mid-growing-season soil respiration measurements indicate that grassland soils are a “hot spot” for soil carbon storage and soil carbon dioxide efflux. Even though shrub, steppe, and mixed vegetation had lower average soil carbon stocks (14.66 – 20.17 kg C m−2), these vegetation types played an important role in carbon cycling at the landscape scale because they cover approximately 50 percent of the terrestrial landscape and store approximately 68 percent of the landscape soil organic carbon. The heterogeneous soil carbon stocks in this landscape may be sensitive to key environmental changes, such as shrub expansion and climate change. These environmental drivers could possibly result in a trend toward decreased soil carbon storage and increased release of greenhouse gases into the atmosphere.

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