Contributors | Affiliation | Role |
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Zimmerman, Richard C. | Old Dominion University (ODU) | Principal Investigator, Contact |
Hill, Victoria J. | Old Dominion University (ODU) | Co-Principal Investigator |
Swingle, W. Mark | Virginia Aquarium | Co-Principal Investigator |
Ruble, David | Old Dominion University (ODU) | Contact |
Gegg, Stephen R. | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Eelgrass Climate Impacts
Experimental conditions, growth and survival of eelgrass
CTD Data - Date, Salinity, Water Temperature
Salinity: Conductivity and temperature data were recorded at 10 minute intervals using a factory-calibrated CTD (Sea-Bird Model SBE-37) placed in Experimental Tank 11.
Temperature data were recorded in each of the 20 experimental tanks using Omega 4404 precision thermistor elements connected to a custom-designed voltage divider circuit linked to a National Instruments data logger controlled by custom software written in LabView.
Salinity - Raw data were processed to temperature (° C) and salinity (practical salinity scale) using instrument-specific software (Sea Term Ver. 1.59 and Data Conversion Ver. 7.22.5, provided by Sea Bird). Mean daily values of temperature and salinity were calculated from the 10 minute records and provided in this spreadsheet. 10 minute records of the processed data, along with raw data files are available from the PIs, upon request.
Temperature - Thermistors were individually calibrated to a precision of 0.01 ° C across a temperature range of 5° to 30° C in a temperature controlled water bath every six months. Mean daily values of temperature for each tank were calculated from the 10 minute records and provided in this spreadsheet. 10 minute records of the processed data, along with raw data files are available from the PIs, upon request.
BCO-DMO Processing Notes
- Generated from original file: "BORG_SeaGrass_Full_data_Records.xlsx" Sheet: "CTD" contributed by David Ruble
- Approx Lat/Lon of Virginia Aquarium Climate Change Facility appended to enable data discovery in MapServer
- Parameters modified to conform to BCO-DMO parameter naming conventions (Choosing a Parameter Name)
File |
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CTD_Data.csv (Comma Separated Values (.csv), 23.36 KB) MD5:305f96076d1383f0a9d2dbc35edb22d8 Primary data file for dataset ID 504838 |
Parameter | Description | Units |
Lab_Id | Lab Id – Lab identifier where experiments were conducted | text |
Lat | Approximate Latitude Position of Lab; South is negative | decimal degrees |
Lon | Approximate Longitude Position of Lab; West is negative | decimal degrees |
date | Date | yyyymmdd |
sal | Salinity | PSS |
Wt | Water temperature | degreesC |
Dataset-specific Instrument Name | Sea-Bird Model SBE-37 |
Generic Instrument Name | CTD Sea-Bird MicroCAT 37 |
Dataset-specific Description | Salinity: Conductivity and temperature data were recorded at 10 minute intervals using a factory-calibrated CTD (Sea-Bird Model SBE-37) placed in Experimental Tank 11. |
Generic Instrument Description | The Sea-Bird MicroCAT CTD unit is a high-accuracy conductivity and temperature recorder based on the Sea-Bird SBE 37 MicroCAT series of products. It can be configured with optional pressure sensor, internal batteries, memory, built-in Inductive Modem, integral Pump, and/or SBE-43 Integrated Dissolved Oxygen sensor. Constructed of titanium and other non-corroding materials for long life with minimal maintenance, the MicroCAT is designed for long duration on moorings.
In a typical mooring, a modem module housed in the buoy communicates with underwater instruments and is interfaced to a computer or data logger via serial port. The computer or data logger is programmed to poll each instrument on the mooring for its data, and send the data to a telemetry transmitter (satellite link, cell phone, RF modem, etc.). The MicroCAT saves data in memory for upload after recovery, providing a data backup if real-time telemetry is interrupted. |
Dataset-specific Instrument Name | Omega 4404 precision thermistor elements |
Generic Instrument Name | Thermistor |
Dataset-specific Description | Temperature data were recorded in each of the 20 experimental tanks using Omega 4404 precision thermistor elements connected to a custom-designed voltage divider circuit linked to a National Instruments data logger controlled by custom software written in LabView. |
Generic Instrument Description | A thermistor is a type of resistor whose resistance varies significantly with temperature, more so than in standard resistors. The word is a portmanteau of thermal and resistor. Thermistors are widely used as inrush current limiters, temperature sensors, self-resetting overcurrent protectors, and self-regulating heating elements.
Thermistors differ from resistance temperature detectors (RTD) in that the material used in a thermistor is generally a ceramic or polymer, while RTDs use pure metals. The temperature response is also different; RTDs are useful over larger temperature ranges, while thermistors typically achieve a higher precision within a limited temperature range, typically 90C to 130C. |
Website | |
Platform | Virginia Aquarium Climate Change Facility |
Start Date | 2011-02-01 |
End Date | 2015-01-31 |
Description | Laboratory experiments conducted from 1 May 2013 to 31 Jan 2013 at Virginia Aquarium Climate Change Facility, Virginia Beach VA |
Project abstract from the NSF proposal:
The past few decades have accumulated mounting evidence of profound anthropogenic effects on fundamental biogeochemical processes across the planet, especially in coastal environments that support a diverse array of highly productive ecosystems including coral reefs, seagrass meadows, and estuaries. The ecological significance of seagrasses is largely due to the remarkable degree of adaptation they exhibit to a submerged aquatic existence. Despite numerous successful adaptations, however, seagrasses have high light requirements that make them vulnerable to anthropogenic disturbances. The paradoxical vulnerability results largely from their high reliance on dissolved aqueous CO2 for photosynthesis. The potential for rising atmospheric CO2 concentrations to have significant warming impacts on the global climate has long been recognized, but the potential impacts of the "other CO2 problem", also known as ocean acidification, have only recently begun to be appreciated. As with other impacts of climate change, the increased concentrations of dissolved aqueous CO2 [CO2 (aq)] in the oceans of the world will elicit both negative and positive responses among organisms, ultimately potentiating ecological losers and winners. This project will explore the response of eelgrass to increased CO2 (aq) within the context of a warming coastal ocean using a combination of manipulative experiments, physiological/biochemical investigations and mathematical modeling. The investigators hypothesize that rising CO2(aq) will increase the high temperature tolerance of plants by improving the Q10 response of photosynthesis relative to respiration, thereby leading to higher growth rates, improved survival of vegetative shoots at high temperature, and even flowering output and seed production. This project will investigate the key relationships between environmental parameters that have both negative (ocean warming) and positive (ocean carbonation) impacts on the light requirements and dynamics of carbon balance in these critically important marine angiosperms. By focusing on Chesapeake populations growing near the southern limit of eelgrass distribution on the Atlantic coast, the investigators will gain predictive insight into how climate change may alter the geographic distribution of this critically important species in other coastal environments that may be subjected to less temperature stress but similar levels of ocean carbonation.
Objectives: The overall goal of the proposed research will be to develop a predictive mechanistic understanding of the simultaneous impacts of water temperature, [CO2(aq)] and [HCO3-] on the photosynthetic metabolism, vegetative growth and reproductive success of Zostera marina L. We will address the following questions, (1) To what extent is the upper thermal limit of eelgrass controlled by CO2(aq) availability, (2) Will prolonged CO2(aq) enrichment affect the ability of eelgrass to utilize HCO3- for photosynthesis, (3) Does prolonged CO2(aq) enrichment increase seed production and viability, and (4) Does CO2(aq) enrichment affect nutritional quality of seagrass tissue, particularly C:N ratios and protein content?
These experiments will be carried out at an experimental CO2(aq) enrichment facility which is being constructed at the Virginia Aquarium & Marine Science Center, adjacent to Owl Creek and Rudee Inlet, in Virginia Beach, VA.
Data Inventory
1) Weather and hydrographic data for Owl Creek Experimental Facility. Metadata and time series observations of irradiance, water temperature, pH, salinity, alkalinity, CO2 and dissolved nutrients will be posted on our web site, and final version data will be supplied to NODC for permanent archive.
2) Experimental metadata from the tanks (pH, temperature, eelgrass abundance and survival, growth rates, metabolic rates, etc.) will also be posted on our website listed above. Final data will be supplied to NODC and/or other databases as appropriate and as they become available.
Project data will also be contributed to thematic databases, including SeaBASS operated by NASA, WOOD operated by ONR, as well as NODC.
Preliminary results may be posted at the group's Web site hosted at ODU:
http://sci.odu.edu/oceanography/directory/faculty/zimmerman/researchpage/index.shtml
Funding Source | Award |
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NSF Division of Ocean Sciences (NSF OCE) |