| Contributors | Affiliation | Role |
|---|---|---|
| Christensen, John P | Green Eyes LLC | Principal Investigator |
| Runge, Jeffrey A. | Gulf of Maine Research Institute (GMRI) | Co-Principal Investigator |
| Copley, Nancy | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
During the eggs experiments, the general conditions within the tanks were monitored using electrodes for temperature, pH and its millivolt output, salinity, and dissolved oxygen. Results are published in Preziosi et al (2017), Table 1.
The sensors were a model 55 YSI dissolved oxygen meter and an Orion Four Star pH conductivity meter using a gel-filled model number 9107WMMD pH/ATC Triode. Each instrument was calibrated according to the normal manufacturer's instructions using off the shelf calibration solutions. During and following experiment 8, the pH electrode readings appeared abnormal and are likely invalid. The electrode pH was only used as a guide for the sampling crew.
BCO-DMO Processing Notes:
- added conventional header with dataset name, PI name, version date
- modified parameter names to conform with BCO-DMO naming conventions
- hid separator rows (all -99), and duplicate columns
- added columns for ISO_DateTime_local and yrday_local
| File |
|---|
table1.csv (Comma Separated Values (.csv), 31.77 KB) MD5:b44a26295294da89e56c3babc77d517d Primary data file for dataset ID 738447 |
| Parameter | Description | Units |
| EXPERIMENT | Number of the experiment | unitless |
| EVENT | Sampling or maintenance # | unitless |
| YEAR | Sampling date - year | year |
| MONTH | Sampling date - month | unitless |
| DAY | Sampling date - day | unitless |
| HR | Sampling time - hour of the day | unitless |
| MIN | Sampling time - minutes of the hour | unitless |
| TIME_elapsed | Time from internment of the eggs | hours |
| PURPOSE | Sampling or maintenance type | unitless |
| ROWTYPE | Labels of the subsequent rows | unitless |
| TEMP_1 | Temperature of the tank | degrees Celsius |
| PH_1 | pH in the tank | pH units |
| PHMV_1 | mv output of the pH electrode | millivolts |
| SAL_1 | Salinity in the tank | parts per thousand (ppt) |
| DO_1 | Dissolved Oxygen in the tank | % saturation |
| TEMP_2 | Temperature of the tank | degrees Celsius |
| PH_2 | pH in the tank | pH units |
| PHMV_2 | mv output of the pH electrode | millivolts |
| SAL_2 | Salinity in the tank | parts per thousand (ppt) |
| DO_2 | Dissolved Oxygen in the tank | % saturation |
| TEMP_3 | Temperature of the tank | degrees Celsius |
| PH_3 | pH in the tank | pH units |
| PHMV_3 | mv output of the pH electrode | millivolts |
| SAL_3 | Salinity in the tank | parts per thousand (ppt) |
| DO_3 | Dissolved Oxygen in the tank | % saturation |
| TEMP_4 | Temperature of the tank | degrees Celsius |
| PH_4 | pH in the tank | pH units |
| PHMV_4 | mv output of the pH electrode | millivolts |
| SAL_4 | Salinity in the tank | parts per thousand (ppt) |
| DO_4 | Dissolved Oxygen in the tank | % saturation |
| TEMP_5 | Temperature of the tank | degrees Celsius |
| PH_5 | pH in the tank | pH units |
| PHMV_5 | mv output of the pH electrode | millivolts |
| SAL_5 | Salinity in the tank | parts per thousand (ppt) |
| DO_5 | Dissolved Oxygen in the tank | % saturation |
| COMMENTS | investigator notes | unitless |
| ISO_DateTime_local | ISO-formatted date and time | |
| yrday_local | local day and decimal time, as 326.5 for the 326th day of the year, or November 22 at 1200 hours (noon). | unitless |
| Dataset-specific Instrument Name | Orion Four Star pH conductivity meter |
| Generic Instrument Name | Benchtop pH Meter |
| Dataset-specific Description | Used with a gel-filled model number 9107WMMD pH/ATC Triode |
| Generic Instrument Description | An instrument consisting of an electronic voltmeter and pH-responsive electrode that gives a direct conversion of voltage differences to differences of pH at the measurement temperature. (McGraw-Hill Dictionary of Scientific and Technical Terms)
This instrument does not map to the NERC instrument vocabulary term for 'pH Sensor' which measures values in the water column. Benchtop models are typically employed for stationary lab applications. |
| Dataset-specific Instrument Name | model 55 YSI dissolved oxygen meter |
| Generic Instrument Name | Oxygen Sensor |
| Dataset-specific Description | Used to measure dissolved oxygen in the experimental tanks. |
| Generic Instrument Description | An electronic device that measures the proportion of oxygen (O2) in the gas or liquid being analyzed |
| Dataset-specific Instrument Name | Orion Four Start pH conductivity meter |
| Generic Instrument Name | Conductivity Meter |
| Dataset-specific Description | Used to measure the approximate salinities. |
| Generic Instrument Description | Conductivity Meter - An electrical conductivity meter (EC meter) measures the electrical conductivity in a solution. Commonly used in hydroponics, aquaculture and freshwater systems to monitor the amount of nutrients, salts or impurities in the water. |
The project description is a modification of the original NSF award abstract.
This research project is part of the larger NSF funded CRI-OA collaborative research initiative and was funded as an Ocean Acidification-Category 1, 2010 award. While attention concerning impacts of predicted acidification of the world's oceans has focused on calcifying organisms, non-calcifying plankton may also be vulnerable. In this project, the investigator will evaluate the potential for impacts of ocean acidification on the reproductive success of three species of planktonic copepods in the genus Calanus that are prominent in high latitude oceans. C. finmarchicus dominates the mesozooplankton biomass across much of the coastal and deep North Atlantic Ocean. C. glacialis and the larger C. hyperboreus are among the most abundant planktonic copepods in the Arctic Ocean. Previous research showed that hatching success of C. finmarchicus eggs was severely inhibited by increased CO2 and lower pH in seawater, but only tested at an extreme level. Preliminary results in the investigator's laboratory indicate that hatching success of C. finmarchicus is substantially reduced at increased seawater CO2 concentrations corresponding to pH levels between 7.9 and 7.5. Predictions of likely decline of surface pH levels to 7.7-7.8 over the next century raise questions about impacts on Calanus population dynamics if these preliminary results are confirmed. C. finmarchicus, for example, is presently at the southern edge of its range in the Gulf of Maine. The combination of higher surface layer temperature and lower pH may inhibit reproductive success during the late summer/fall bloom, which the PI hypothesize is critical to sustain the overwintering stock in this region. The investigators will collect C. finmarchicus females from the Gulf of Maine and, with the assistance of Canadian colleagues, C. glacialis and C. hyperboreus females from the deep lower St. Lawrence Estuary. They will conduct laboratory experiments in which hatching success, development and growth of Calanus nauplius stages are measured in controls of natural seawater and at a series of treatments in which CO2 concentrations, pH and temperature are rigorously controlled to represent possible future states of the northern ocean. The investigators will measure present surface and deep pCO2 and pH across the Gulf of Maine, including its deep basins, during a research cruise. The study will evaluate the hypothesis that predicted levels of CO2 increase in the northern ocean will impact population dynamics of the Calanus species. Using the results from the research cruise and a recently developed 1-D, Individual-Based life cycle model, the PI will explore in detail scenarios of impact of higher temperature and lower surface and deep pH on population dynamics of C. finmarchicus in the Gulf of Maine.
The lipid-rich Calanus species are considered key intermediary links between primary production and higher trophic levels in North Atlantic and Arctic Ocean food webs. Impacts of higher surface temperature and lower pH on reproductive success may potentially lead to profound changes in energy transfer and structure of pelagic ecosystems in the northern oceans. In the Gulf of Maine, C. finmarchicus serves as primary prey for herring, sand lance, and mackerel, as well as the endangered northern right whale, warranting thorough evaluation of ocean acidification effects on its population dynamics.
NSF Climate Research Investment (CRI) activities that were initiated in 2010 are now included under Science, Engineering and Education for Sustainability NSF-Wide Investment (SEES). SEES is a portfolio of activities that highlights NSF's unique role in helping society address the challenge(s) of achieving sustainability. Detailed information about the SEES program is available from NSF (https://www.nsf.gov/funding/pgm_summ.jsp?pims_id=504707).
In recognition of the need for basic research concerning the nature, extent and impact of ocean acidification on oceanic environments in the past, present and future, the goal of the SEES: OA program is to understand (a) the chemistry and physical chemistry of ocean acidification; (b) how ocean acidification interacts with processes at the organismal level; and (c) how the earth system history informs our understanding of the effects of ocean acidification on the present day and future ocean.
Solicitations issued under this program:
NSF 10-530, FY 2010-FY2011
NSF 12-500, FY 2012
NSF 12-600, FY 2013
NSF 13-586, FY 2014
NSF 13-586 was the final solicitation that will be released for this program.
PI Meetings:
1st U.S. Ocean Acidification PI Meeting(March 22-24, 2011, Woods Hole, MA)
2nd U.S. Ocean Acidification PI Meeting(Sept. 18-20, 2013, Washington, DC)
3rd U.S. Ocean Acidification PI Meeting (June 9-11, 2015, Woods Hole, MA – Tentative)
NSF media releases for the Ocean Acidification Program:
Press Release 10-186 NSF Awards Grants to Study Effects of Ocean Acidification
Discovery Blue Mussels "Hang On" Along Rocky Shores: For How Long?
Press Release 13-102 World Oceans Month Brings Mixed News for Oysters
The Ocean Carbon and Biogeochemistry (OCB) program focuses on the ocean's role as a component of the global Earth system, bringing together research in geochemistry, ocean physics, and ecology that inform on and advance our understanding of ocean biogeochemistry. The overall program goals are to promote, plan, and coordinate collaborative, multidisciplinary research opportunities within the U.S. research community and with international partners. Important OCB-related activities currently include: the Ocean Carbon and Climate Change (OCCC) and the North American Carbon Program (NACP); U.S. contributions to IMBER, SOLAS, CARBOOCEAN; and numerous U.S. single-investigator and medium-size research projects funded by U.S. federal agencies including NASA, NOAA, and NSF.
The scientific mission of OCB is to study the evolving role of the ocean in the global carbon cycle, in the face of environmental variability and change through studies of marine biogeochemical cycles and associated ecosystems.
The overarching OCB science themes include improved understanding and prediction of: 1) oceanic uptake and release of atmospheric CO2 and other greenhouse gases and 2) environmental sensitivities of biogeochemical cycles, marine ecosystems, and interactions between the two.
The OCB Research Priorities (updated January 2012) include: ocean acidification; terrestrial/coastal carbon fluxes and exchanges; climate sensitivities of and change in ecosystem structure and associated impacts on biogeochemical cycles; mesopelagic ecological and biogeochemical interactions; benthic-pelagic feedbacks on biogeochemical cycles; ocean carbon uptake and storage; and expanding low-oxygen conditions in the coastal and open oceans.
| Funding Source | Award |
|---|---|
| NSF Division of Ocean Sciences (NSF OCE) |