Experimental tank parameters throughout the life of Clathromorphum compactum and C. nereostratum calcification experiment from from 2015-2016 (CorallineAlgaePaleo-pH project)
Project
| Contributors | Affiliation | Role |
|---|---|---|
| Ries, Justin B. | Northeastern University | Principal Investigator, Contact |
| Rasher, Douglas B. | Bigelow Laboratory for Ocean Sciences | Co-Principal Investigator |
| Williams, Branwen | University of California-San Diego Scripps (UCSD-SIO) | Co-Principal Investigator |
| Westfield, Isaac | Northeastern University | Scientist |
| Newman, Sawyer | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Abstract
Methodology:
Sampling and analytical procedures:
C. compactum and C. nereostratum cultured for 4 months under 12 pCO2/T treatments in thirty-six, 42-liter aquaria.
Seawater samples were obtained every ~14 days using 250 mL ground-glass-stoppered borosilicate glass bottles for measurement of total alkalinity (TA) and dissolved inorganic carbon (DIC) and other carbonate parameters.
Temp, salinity, pH measured three times weekly.
For buoyant weight, specimens were suspended beneath a balance in an aquarium at 4 cm depth in seawater of constant temperature and salinity.
Specimens were dosed with calcein before the experiment and the vertical growth was determined by measuring the vertical growth from the resulting calcein line to the surface.
CO2Sys used to calculate all carbonate parameters, including pCO2.
| File |
|---|
Salinity_Temp_PCO2_tank_parameters.csv (Comma Separated Values (.csv), 97.79 KB) MD5:1c9da6167e9082edb27b2b9393c81089 Primary data file for dataset ID 872498 |
Relationship Description: These tank conditions were measured during the experiments represented by the dataset "Crustose coralline algae calcification experiment data" (871633).
| Parameter | Description | Units |
| Date | Date of sampling measurement | unitless |
| Mean_pCO2 | Mean pCO2 of experimental tank | uatm |
| Mean_Temp | Mean temperature of experimental tank | degrees Celsius |
| Mean_pH | Mean pH of experimental tank | unitless |
| Tank | Tank number within a temperature/pCO2 combination | unitless |
| Group_ID | Cominations of experimental conditions and Tank number used to create a unique identifier for groups within the experiment | unitless |
| Salinity | Salinity of the experimental tank | psu |
| Temp | Temperature of the experimental tank | degrees Celsius |
| pCO2 | pCO2 of the experimental tank | uatm |
| pH | pH of the experimental tank | unitless |
| Dataset-specific Instrument Name | VINDTA 3C (Marianda Corporation, Kiel, Germany) |
| Generic Instrument Name | MARIANDA VINDTA 3C total inorganic carbon and titration alkalinity analyser |
| Dataset-specific Description | Measures total alkalinity and DIC using closed-cell potentiometric Gran titration and coulometry (UIC 5400), with both methods calibrated using certified Dickson DIC/TA standards. |
| Generic Instrument Description | The Versatile INstrument for the Determination of Total inorganic carbon and titration Alkalinity (VINDTA) 3C is a laboratory alkalinity titration system combined with an extraction unit for coulometric titration, which simultaneously determines the alkalinity and dissolved inorganic carbon content of a sample. The sample transport is performed with peristaltic pumps and acid is added to the sample using a membrane pump. No pressurizing system is required and only one gas supply (nitrogen or dry and CO2-free air) is necessary. The system uses a Metrohm Titrino 719S, an ORION-Ross pH electrode and a Metrohm reference electrode. The burette, the pipette and the analysis cell have a water jacket around them. Precision is typically +/- 1 umol/kg for TA and/or DIC in open ocean water. |
| Dataset-specific Instrument Name | AccuFet™ Solid-State pH probe |
| Generic Instrument Name | pH Sensor |
| Dataset-specific Description | AccuFet™ Solid-State pH probe, calibrated with 7.00 and 10.01 NBS buffers (for slope of calibration) and a Dickson Lab DIC/TA standard (for y-intercept of calibration). |
| Generic Instrument Description | An instrument that measures the hydrogen ion activity in solutions.
The overall concentration of hydrogen ions is inversely related to its pH. The pH scale ranges from 0 to 14 and indicates whether acidic (more H+) or basic (less H+). |
| Dataset-specific Instrument Name | High precision partial-immersion glass thermometer |
| Generic Instrument Name | Thermometer |
| Dataset-specific Description | High precision partial-immersion glass thermometer (precision ±0.3%; accuracy ±0.4%). |
| Generic Instrument Description | A device designed to measure temperature. |
| Dataset-specific Instrument Name | YSI 3200 (Yellow Springs, Ohio, USA) |
| Generic Instrument Name | YSI Professional Plus Multi-Parameter Probe |
| Dataset-specific Description | YSI 3200 (Yellow Springs, Ohio, USA) conductivity probe with a cell constant of k = 10. |
| Generic Instrument Description | The YSI Professional Plus handheld multiparameter meter provides for the measurement of a variety of combinations for dissolved oxygen, conductivity, specific conductance, salinity, resistivity, total dissolved solids (TDS), pH, ORP, pH/ORP combination, ammonium (ammonia), nitrate, chloride and temperature. More information from the manufacturer. |
Collaborative Research: Development and application of a method using coralline algae to reconstruct past changes in pH and impacts on calcification (CorallineAlgaePaleo-pH)
Description from NSF award abstract:
The impacts of recent and future human-caused increases in atmospheric CO2 on the acidity (pH) of shallow cold-water marine environments (a process known as "ocean acidification"), and on the organisms that inhabit them, are poorly understood. This is due, in part, to the difficulty in reconstructing past changes in ocean chemistry in these remote environments. This research seeks to develop and apply a technique to reconstruct past seawater pH from boron isotope signatures in long-lived crustose coralline alga that are widespread throughout shallow, cold-water marine environments. In addition, the research will evaluate the impact of changing seawater pH on the growth rate of these ecologically important organisms, which are thought to be particularly vulnerable to ocean acidification because of the high magnesium content of their skeleton. Overall, this project will advance understanding of ocean acidification in shallow, cold-water environments, and provide key information to evaluate the impact that changes in ocean pH have had on organisms inhabiting these environments. The outcomes of this work will provide important information to policy makers and legislators seeking to mitigate the negative effects of rising atmospheric CO2 on these fragile, high-latitude marine ecosystems.
Funding supports a graduate student, numerous undergraduate researchers, and a new collaboration between two early career faculty members. Outreach includes mentoring high school students from groups underrepresented in the sciences through the Scripps College Academy and production of an educational film on the biological impacts of ocean acidification. The research team will strengthen international ties through collaboration with Canadian and UK scientists, while helping maintain US-based scientists at the forefront of this important sub-field of ocean acidification research.
The work plan includes three main parts: (1) developing the first laboratory-derived and field-verified calibration of the delta11B-proxy of paleoseawater pH for coralline algae, (2) generating the first high-resolution, multi-centennial dataset of high-latitude seawater pH before (ca. 1365 to 1760 AD; i.e., "baseline") and after (ca. 1760 AD to present; i.e., "anthropogenic signal") the Industrial Revolution, and (3) evaluating the impact of anthropogenic ocean acidification on the linear extension, density, and ultrastructure of skeletons produced by an ecologically important, habitat-forming coralline red alga. The associated objectives are: (1) to provide a new tool for reconstructing paleo-seawater pH, (2) to generate historical records of ocean acidification that would elucidate the rate and magnitude of high-latitude ocean acidification that could be used to verify predictive models, and (3) to establish empirical relationships between ocean acidification and coralline algal calcification that would inform predictions of future impacts of ocean acidification on high-latitude marine calcifiers.
Additional information may be found on the following lab websites:
Ries Lab - http://nuweb2.neu.edu/rieslab/
Williams Marine Environmental Change (MEC) Lab - https://branwenwilliams.com/
| Funding Source | Award |
|---|---|
| NSF Arctic Sciences (NSF ARC) | |
| NSF Division of Ocean Sciences (NSF OCE) | |
| NSF Division of Ocean Sciences (NSF OCE) |
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