Climate Drivers Linked to Changing Seasonality of Alaska Coastal Tundra Vegetation Productivity

The mechanisms driving trends and variability of the normalized difference vegetation index (NDVI) for tundra in Alaska along the Beaufort, east Chukchi, and east Bering Seas for 1982-2013 are evaluated in the context of remote sensing, reanalysis, and meteorological station data as well as regional...

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Bibliographic Details
Published in:Earth interactions 2015-12, Vol.19 (19), p.1-29
Main Authors: Bieniek, Peter A, Bhatt, Uma S, Walker, Donald A, Raynolds, Martha K, Comiso, Josefino C, Epstein, Howard E, Pinzon, Jorge E, Tucker, Compton J, Thoman, Richard L, Tran, Huy, Mölders, Nicole, Steele, Michael, Zhang, Jinlun, Ermold, Wendy
Format: Article
Language:English
Subjects:
Air circulation
Applied physics
Atmospheric circulation
Atmospheric circulation changes
Atmospheric models
Atmospheric moisture
Biology
Brackish
Breeze circulation
Circulation
Climate
Cloud cover
Cloudiness
Coasts
Cooling
Entrepreneurship
Feedback
Growing season
Ice
Laboratories
Land surface temperature
Marine
Meteorology
Modelling
Moisture
Normalized difference vegetative index
Precipitation
Productivity
Remote sensing
Research centers
Science
Sea level
Sea level pressure
Seasonal variations
Seasonality
Seasons
Snow accumulation
Snow depth
Spring
Summer
Surface temperature
Taiga & tundra
Trends
Tundra
Variability
Vegetation
Vegetation index
Weather stations
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Summary:The mechanisms driving trends and variability of the normalized difference vegetation index (NDVI) for tundra in Alaska along the Beaufort, east Chukchi, and east Bering Seas for 1982-2013 are evaluated in the context of remote sensing, reanalysis, and meteorological station data as well as regional modeling. Over the entire season the tundra vegetation continues to green; however, biweekly NDVI has declined during the early part of the growing season in all of the Alaskan tundra domains. These springtime declines coincide with increased snow depth in spring documented in northern Alaska. The tundra region generally has warmed over the summer but intraseasonal analysis shows a decline in midsummer land surface temperatures. The midsummer cooling is consistent with recent large-scale circulation changes characterized by lower sea level pressures, which favor increased cloud cover. In northern Alaska, the sea-breeze circulation is strengthened with an increase in atmospheric moisture/cloudiness inland when the land surface is warmed in a regional model, suggesting the potential for increased vegetation to feedback onto the atmospheric circulation that could reduce midsummer temperatures. This study shows that both large- and local-scale climate drivers likely play a role in the observed seasonality of NDVI trends.
ISSN:1087-3562
1087-3562
DOI:10.1175/EI-D-15-0013.1