| Contributors | Affiliation | Role |
|---|---|---|
| Peterson, Richard N. | Coastal Carolina University | Principal Investigator |
| Montoya, Joseph | Georgia Institute of Technology (GA Tech) | Co-Principal Investigator |
| Subramaniam, Ajit | Lamont-Doherty Earth Observatory (LDEO) | Co-Principal Investigator |
| Biddle, Mathew | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Water samples for radium isotope analysis were collected from both the ship’s clean underway intake system (‘U’ designator in data sheet) and niskin bottles attached to the CTD rosette (‘C’ designator in data sheet). Salinity data derived from ship’s clean underway intake system with SBE 21 SEACAT Thermosaliograph.
Water samples were filtered through 47 mm GFF filters (unless otherwise noted), then passed slowly through 25 g (dry) acrylic fibers impregnated with MnO2 (Moore, 1976). Fibers were then washed 10x with Ra-free freshwater to remove salts and dried to a mass between 35 and 57 g for optimal humidity levels (Sun and Torgersen, 1998). Fibers were then immediately counted on a Radium Delayed Coincidence Counter (RaDeCC; Moore and Arnold, 1996) for total Ra-224 and Ra-223. Roughly 3 weeks later, fibers were counted again for supported Ra-224. Thus, excess (‘XS’) Ra-224 is the difference between total and supported Ra-224 measurements. Ra-226 activities were then measured on a radon emanation line as per Peterson et al. (2009).
Minimum detectable activities (dpm/100L) are calculated based on Currie (1968). Any measured values lower than the minimum detectable activity is labeled ‘BD’
BCO-DMO Processing Notes:
- adjusted the date format from mm/dd/yy to yyyy-mm-dd in the columns date and date_time
- added conventional header with dataset name, PI name, version date
- modified parameter names to conform with BCO-DMO naming conventions
| File |
|---|
radium.csv (Comma Separated Values (.csv), 27.18 KB) MD5:0d94d1f6c30db68da9201a6f8a9a0662 Primary data file for dataset ID 753837 |
| Parameter | Description | Units |
| U_or_C | Underway (surface) or CTD sample designator | unitless |
| Station | Station # | unitless |
| Cast | Cast # at each station | unitless |
| Date | Local date (EST) sample collected | unitless |
| Time | Local time (EST) sample collected | unitless |
| Date_Time | Date and time (GMT) sample collected | yyyy-MM-dd HH:mm |
| Latitude | Sampling latitude | decimal degrees |
| Longitude | Sampling longitude | decimal degrees |
| Depth | Water depth of sample collection | meters (m) |
| Salinity | Salinity of ship’s seawater intake system | unitless |
| Sample_Volume | Water sample volume | liters (L) |
| Ra223_Activity | Radium-223 activity | dpm/100L |
| Ra223_Unc | 1-σ analytical uncertainty for Ra223 | dpm/100L |
| XS_Ra224_Activity | Excess radium-224 activity | dpm/100L |
| XS_Ra224_Unc | 1-σ analytical uncertainty for Ra224 | dpm/100L |
| Ra226_Activity | Radium-226 activity | dpm/100L |
| Ra226_Unc | 1-σ analytical uncertainty for Ra226 | dpm/100L |
| Comments | Pertinent notes regarding sample collection | unitless |
| Dataset-specific Instrument Name | niskin bottles |
| Generic Instrument Name | Niskin bottle |
| Dataset-specific Description | niskin bottles attached to the CTD rosette (‘C’ designator in data sheet). |
| Generic Instrument Description | A Niskin bottle (a next generation water sampler based on the Nansen bottle) is a cylindrical, non-metallic water collection device with stoppers at both ends. The bottles can be attached individually on a hydrowire or deployed in 12, 24, or 36 bottle Rosette systems mounted on a frame and combined with a CTD. Niskin bottles are used to collect discrete water samples for a range of measurements including pigments, nutrients, plankton, etc. |
| Dataset-specific Instrument Name | ship’s clean underway intake system |
| Generic Instrument Name | Pump - Surface Underway Ship Intake |
| Dataset-specific Description | Water samples for radium isotope analysis were collected from both the ship’s clean underway intake system (‘U’ designator in data sheet) |
| Generic Instrument Description | The 'Pump-underway ship intake' system indicates that samples are from the ship's clean water intake pump. This is essentially a surface water sample from a source of uncontaminated near-surface (commonly 3 to 7 m) seawater that can be pumped continuously to shipboard laboratories on research vessels. There is typically a temperature sensor near the intake (known as the hull temperature) to provide measurements that are as close as possible to the ambient water temperature. The flow from the supply is typically directed through continuously logged sensors such as a thermosalinograph and a fluorometer. Water samples are often collected from the underway supply that may also be referred to as the non-toxic supply. Ideally the data contributor has specified the depth in the ship's hull at which the pump is mounted. |
| Dataset-specific Instrument Name | Radium Delayed Coincidence Counter |
| Generic Instrument Name | Radium Delayed Coincidence Counter |
| Dataset-specific Description | Radium isotopes (224Ra and 223Ra) were analyzed with a Radium Delayed Coincidence Counter (Moore and Arnold, 1996). |
| Generic Instrument Description | The RaDeCC is an alpha scintillation counter that distinguishes decay events of short-lived radium daughter products based on their contrasting half-lives. This system was pioneered by Giffin et al. (1963) and adapted for radium measurements by Moore and Arnold (1996).
References:
Giffin, C., A. Kaufman, W.S. Broecker (1963). Delayed coincidence counter for the assay of actinon and thoron. J. Geophys. Res., 68, pp. 1749-1757.
Moore, W.S., R. Arnold (1996). Measurement of 223Ra and 224Ra in coastal waters using a delayed coincidence counter. J. Geophys. Res., 101 (1996), pp. 1321-1329.
Charette, Matthew A.; Dulaiova, Henrieta; Gonneea, Meagan E.; Henderson, Paul B.; Moore, Willard S.; Scholten, Jan C.; Pham, M. K. (2012). GEOTRACES radium isotopes interlaboratory comparison experiment. Limnology and Oceanography - Methods, vol 10, pg 451. |
| Dataset-specific Instrument Name | SBE 21 SEACAT Thermosaliograph |
| Generic Instrument Name | Sea-Bird SeaCAT Thermosalinograph SBE 21 |
| Dataset-specific Description | Salinity data derived from ship’s clean underway intake system with SBE 21 SEACAT Thermosaliograph. |
| Generic Instrument Description | A platinum-electrode conductivity sensor and a thermistor mounted in a corrosion-resistant plastic and titanium housing designed to be continuously plumbed into a vessel's pumped seawater supply. The instrument may be interfaced to a remote SBE 38 temperature sensor mounted either on the hull or in the seawater inlet. Data are both stored in internal memory and output to a serial port for external logging. Conductivity is measured in the range 0-7 S/m with an accuracy of 0.001 S/m and a resolution of 0.0001 S/m. Housing temperature is measured in the range -5-35C with an accuracy of 0.01 C and a resolution of 0.001 C. Remote temperature is measured in the range -5-35C with an accuracy of 0.001 C and a resolution of 0.0003 C. More information at http://www.seabird.com/products/spec_sheets/21data.htm. |
| Website | |
| Platform | R/V Endeavor |
| Start Date | 2018-05-06 |
| End Date | 2018-06-01 |
| Description | See additional cruise information from the Rolling Deck to Repository (R2R): https://www.rvdata.us/search/cruise/EN614 |
NSF Award Abstract:
This is a focused program of field research in waters of the Western Tropical North Atlantic influenced by the Amazon River Plume during the high river flow season. The Amazon Plume region supports diverse plankton communities in a dynamic system driven by nutrients supplied by transport from the river proper as well as nutrients entrained from offshore waters by physical mixing and upwelling. This creates strong interactions among physical, chemical, and biological processes across a range of spatial and temporal scales. The field program will link direct measurements of environmental properties with focused experimental studies of nutrient supply and nutrient limitation of phytoplankton, as well as the transfer of phytoplankton nitrogen to the zooplankton food web. The Amazon Plume exhibits a close juxtaposition of distinct communities during the high-flow season, making it an ideal site for evaluating how nutrient availability, nutrient supply, and habitat longevity interact to drive offshore ecosystem dynamics and function. This project will include German collaborators and will seamlessly integrate education and research efforts. The investigators and their institutions have a strong commitment to undergraduate and graduate education and to increasing the diversity of the ocean science community through active recruiting and training efforts. The team has a strong track record of involving both undergraduate and graduate students in their field and lab research. The two research cruises planned will provide opportunities for students and technicians to interact with an interdisciplinary and international research team.
The ultimate objectives of this project are to understand the processes and interactions that promote distinct communities of nitrogen-fixing organisms (diazotrophs) and other phytoplankton around the Amazon Plume and to explore the impacts of these diazotroph-rich communities on zooplankton biomass and production. The research team includes scientists with expertise in nutrient and stable isotope biogeochemistry, remote sensing as well as specialists in characterizing water mass origin and history using naturally occurring radium isotopes. This combination of approaches will provide a unique opportunity to address fundamental questions related to plankton community structure, primary production, and links to secondary production in pelagic ecosystems. The project will address the following key questions focused on fundamental issues in plankton ecology resulting from previous research in this region:
A. What mechanisms promote the preferential delivery of bioavailable phosphorus and the resulting strong nitrogen limitation associated with the northern reaches of the Amazon Plume during the high flow season?
B. What factors lead to the clear niche separation between diazotrophs within and around the Amazon Plume and how are the distinct diazotroph communities influenced by hydrographic and biogeochemical controls associated with the Amazon River Plume and offshore upwelling processes?
C. How does the nitrogen fixed by the different types of diazotrophs contribute to secondary production, and how efficiently does diazotroph nitrogen move through the food web?
| Funding Source | Award |
|---|---|
| NSF Division of Ocean Sciences (NSF OCE) |