Contributors | Affiliation | Role |
---|---|---|
Yager, Patricia L. | University of Georgia (UGA) | Principal Investigator, Contact |
Bronk, Deborah A. | Virginia Institute of Marine Science (VIMS) | Co-Principal Investigator |
Frischer, Marc E. | Skidaway Institute of Oceanography (SkIO) | Co-Principal Investigator |
Sipler, Rachel E. | Virginia Institute of Marine Science (VIMS) | Co-Principal Investigator |
Sanderson, Marta P. | Virginia Institute of Marine Science (VIMS) | Data Manager |
Gegg, Stephen R. | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Biological and Chemical Uptake Rate Measurements
"UPTAKE" = Size fractionated uptake rate data
(tbd)
BCO-DMO Processing Notes
- Generated from original file "ARCTICNITRO_MasterDataReport.xlsx, sheet: "Uptake" contributed by Patricia Yager
- "Year" parameter added
- Date reformatted to YYYYMMDD
- Parameter names edited to conform to BCO-DMO naming convention found at Choosing Parameter Name
- "nd" (no data) inserted into blank cells
- Blank lines deleted
File |
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MasterData_Uptake.csv (Comma Separated Values (.csv), 4.89 KB) MD5:09ddd97f47818f37436ebba9caeeb751 Primary data file for dataset ID 535763 |
Parameter | Description | Units |
Year | Collection Year | YYYY |
Sample_ID | Location of sample collection (name) | text |
Date | Date of sample collection (local Alaska time) | YYYYMMDD |
Latitude | Latitude of sample collection | decimal degrees |
Longitude | Longitude of sample collection | decimal degrees |
Size_Fraction | Size Fraction | um |
Depth | Sample Depth | m |
NH4_Specific_Uptake | N uptake from NH4 by organisms of size in size fraction column | 1/h |
NH4_Specific_Uptake_SD | N uptake from NH4 by organisms of size in size fraction column SD | dimensionless |
NO2_Specific_Uptake | N uptake from NO2 by organisms of size in size fraction column | 1/h |
NO2_Specific_Uptake_SD | N uptake from NO2 by organisms of size in size fraction column SD | dimensionless |
NO3_Specific_Uptake | N uptake from NO3 by organisms of size in size fraction column | 1/h |
NO3_Specific_Uptake_SD | N uptake from NO3 by organisms of size in size fraction column SD | dimensionless |
Urea_Specific_Uptake | N uptake from urea by organisms of size in size fraction column | 1/h |
Urea_Specific_Uptake_SD | N uptake from urea by organisms of size in size fraction column SD | dimensionless |
Amino_Acid_Specific_Uptake | N uptake from algal amino acids by organisms of size in size fraction column | 1/h |
Amino_Acid_Specific_Uptake_SD | N uptake from algal amino acids by organisms of size in size fraction column SD | dimensionless |
Thymidine_Specific_Uptake | N uptake from thymidine | 1/h |
Thymidine_Specific_Uptake_SD | N uptake from thymidine SD | dimensionless |
Leucine_Specific_Uptake | N uptake from leucine | 1/h |
Leucine_Specific_Uptake_SD | N uptake from leucine SD | dimensionless |
NH4_Absolute_Uptake | NH4 Absolute Uptake | umol N/L h |
NH4_Absolute_Uptake_SD | NH4 Absolute Uptake SD | dimensionless |
NH4_Absolute_Uptake_Isotope_Dilution_Corrected | NH4 Absolute Uptake Isotope Dilution Corrected | umol N/L h |
NH4_Absolute_Uptake_Isotope_Dilution_Corrected_SD | NH4 Absolute Uptake Isotope Dilution Corrected SD | dimensionless |
NH4_Regeneration | NH4 Regeneration | umol N/L h |
NH4_Regeneration_SD | NH4 Regeneration SD | dimensionless |
NO2_Absolute_Uptake | NO2 Absolute Uptake | umol N/L h |
NO2_Absolute_Uptake_SD | NO2 Absolute Uptake SD | dimensionless |
NO3_Absolute_Uptake | NO3 Absolute Uptake | umol N/L h |
NO3_Absolute_Uptake_SD | NO3 Absolute Uptake SD | dimensionless |
Urea_Absolute_Uptake | Urea Absolute Uptake | umol N/L h |
Urea_Absolute_Uptake_SD | Urea Absolute Uptake SD | dimensionless |
Amino_Acid_Absolute_Uptake | Amino Acid Absolute Uptake | umol N/L h |
Amino_Acid_Absolute_Uptake_SD | Amino Acid Absolute Uptake SD | dimensionless |
Thymidine_Absolute_Uptake | Thymidine Absolute Uptake | umol N/L h |
Thymidine_Absolute_Uptake_SD | Thymidine Absolute Uptake SD | dimensionless |
Leucine_Absolute_Uptake | Leucine Absolute Uptake | umol N/L h |
Leucine_Absolute_Uptake_SD | Leucine Absolute Uptake SD | dimensionless |
Website | |
Platform | ArcticNitro |
Start Date | 2010-08-30 |
End Date | 2012-01-19 |
Description | Extracted from the NSF proposal
Study sites: Because of its unique combination of year-round access to the coastal Arctic Ocean
and strong scientific support system (Barrow Arctic Science Consortium we propose to make our
primary winter and summer measurements from Barrow, Alaska.
At 71°N, Barrow receives 24- hour sunlight between May 10 and August 2, and is in 24-h darkness
between November 18 and January 24. Less than 1 km from shore, shelf depths exceed 10m, and
significantly deeper waters (>100 m) are not far away. Twice each year (January and July) for
two years, working from Barrow, we will use either small boat or skidoo to travel offshore to
sample seawater. We anticipate having access to surface waters of 10-20 m depth within a mile
of the town of Barrow. We plan to sample biological and biogeochemical inventories along three
offshore transects, with 3-5 depths that sample through the surface mixed layer and into the
subsurface layer, accessing both the eastward coastal and the offshore westward currents (Weingartner 2006).
More extensive rate measurements and incubation studies will be made at selected sites and depths
The rationale for the transects is to sample the microbial community response to the cross-shelf
and depth gradients DIN availability. Nearshore stations will be N-limited throughout the water
column in the summer. Offshore stations may have significant NO3 below summer stratification.
As part of SNACS (Study of the Northern Alaska Coastal) C. Ashjian and colleagues have recently
completed summer research near Barrow, using small (43’) boats to investigate environmental controls
on zooplankton populations. They will have nutrient profiles offshore, which will help guide our study.
During the summer, we will coordinate with native Inupiat subsistence whalers (Barrow Whaling Captain
Association. In the winter, safe travel over the ice by foot or snow machine, as far out as the nearshore
lead, will offer access to the ocean using an ice auger. We will not be able to sample far offshore
during winter, but gradients will be weaker due to mixing. |
The Arctic is changing. Warm air is melting the sea ice at an accelerating pace, impacting the marine ecosystem. Further changes on land mean higher river discharge, rising seas, thawing of permafrost, and coastal erosion.
For the Arctic continental shelf, these physical changes impact the creatures that live there in major ways, ultimately altering the pathways and magnitude of energy transfer to fish, sea birds and marine mammals, and impacting the people dependant on those resources. Our challenge today is to understand what is happening in specific Arctic ecosystems to assess future change.
Understanding the microorganisms in Arctic coastal ecosystems is important because microbes dominate the biological biomass, production, and remineralization in marine systems. They are the "composters." Microbes are also the major producers and consumers of carbon dioxide and other greenhouse gases.
This study is focused on the climate-sensitive relationship between these microbes -- particularly the competition for nitrogen between phytoplankton/algae and bacteria -- and the productivity of the food web that depends on these organisms.
Funding Source | Award |
---|---|
NSF Arctic Sciences (NSF ARC) | |
NSF Arctic Sciences (NSF ARC) | |
NSF Arctic Sciences (NSF ARC) |