Light Availability and Phytoplankton Growth Beneath Arctic Sea Ice: Integrating Observations and Modeling

Observations of the seasonal light field in the upper Arctic Ocean are critical to understanding the impacts of changing Arctic ice conditions on phytoplankton growth in the water column. Here we discuss data from a new sensor system, deployed in seasonal ice cover north‐east of Utqiaġvik, Alaska in...

Full description

Bibliographic Details
Published in:Journal of Geophysical Research: Oceans
Main Authors: Hill, Victoria J., Light, Bonnie, Steele, Michael, Zimmerman, Richard C.
Format: Article in Journal/Newspaper
Language:unknown
Published: ODU Digital Commons 2018
Subjects:
Plankton
Water cover
Climate effects
Ocean color
Phytoplankton bloom
Arctic sea ice
Ice conditions
Snow cover
Climate
Marine Biology
Oceanography
Arctic
Arctic Ocean
Climate change
Phytoplankton
Sea ice
Alaska
Online Access:https://digitalcommons.odu.edu/oeas_fac_pubs/292
https://doi.org/10.1029/2017JC013617
https://digitalcommons.odu.edu/context/oeas_fac_pubs/article/1303/viewcontent/Hill_2018_Light_Availability_and_Phytoplankton.pdf
Description
Summary:Observations of the seasonal light field in the upper Arctic Ocean are critical to understanding the impacts of changing Arctic ice conditions on phytoplankton growth in the water column. Here we discuss data from a new sensor system, deployed in seasonal ice cover north‐east of Utqiaġvik, Alaska in March 2014. The system was designed to provide observations of light and phytoplankton biomass in the water column during the formation of surface melt ponds and the transition from ice to open water. Hourly observations of downwelling irradiance beneath the ice (at 2.9, 6.9, and 17.9 m depths) and phytoplankton biomass (at 2.9 m depth) were transmitted via Iridium satellite from 9 March to 10 November 2014. Evidence of an under‐ice phytoplankton bloom (Chl a ∼8 mg m−3) was seen in June and July. Increases in light intensity observed by the buoy likely resulted from the loss of snow cover and development of surface melt ponds. A bio‐optical model of phytoplankton production supported this probable trigger for the rapid onset of under‐ice phytoplankton growth. Once under‐ice light was no longer a limiting factor for photosynthesis, open water exposure almost marginally increased daily phytoplankton production compared to populations that remained under the adjacent ice. As strong effects of climate change continue to be documented in the Arctic, the insight derived from autonomous buoys will play an increasing role in understanding the dynamics of primary productivity where ice and cloud cover limit the utility of ocean color satellite observations.

Similar Items