Carbonate chemistry analyses (total alkalinity, DIC, and d13C of DIC) from discrete bottle samples and CTD data from 12 stations sampled during R/V Endeavor cruise EN669 in the Gulf of Maine during August 2021
Project
| Contributors | Affiliation | Role |
|---|---|---|
| Allen, Katherine A. | University of Maine | Principal Investigator |
| Subhas, Adam V. | Woods Hole Oceanographic Institution (WHOI) | Co-Principal Investigator |
| Woods, Madelyn | University of Maine | Student |
| Rauch, Shannon | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Abstract
These data were collected on R/V Endeavor cruise EN669 from 12 stations across the Gulf of Maine. Water samples were collected using Niskin bottles on the CTD rosette. Equipment included a Seabird Scientific SBE9plus CTD equipped with a transmissometer, oxygen, and fluorescence sensors.
Total Alkalinity, Dissolved Inorganic Carbon (DIC), and d13C-DIC:
Samples for total alkalinity (TA), dissolved inorganic carbon (DIC), and d13C-DIC were collected simultaneously. Water from the Niskins was passed through a 0.45-micron cartridge filter and all bubbles were removed from the line. Ground-glass stoppered 250-milliliter (mL) bottles were rinsed 3 times with flowing, filtered seawater and then filled. Each sample bottle was left to overflow for approximately double the amount of time it took to fill the bottle. Excess water was gently dumped out to leave a ~2-3 mL headspace below the ground glass fitting. Following collection, samples were poisoned with 100 microliters of saturated mercuric chloride solution. Bottles were sealed with a greased stopper (Apiezon-L). A rubber band was placed over the stopper to ensure sample closure. Samples were stored cool and in the dark prior to analysis at the Woods Hole Oceanographic Institution.
DIC and d13C analyses were performed first immediately after opening the bottle. DIC and d13C-DIC were determined simultaneously using an Apollo AS-D1 analyzer connected to a Picarro G-2121i cavity ringdown system on a 5 mL sample of seawater. Samples were run in at least triplicate and calibrated against seawater Certified Reference Materials. Isotopic values were calibrated against an in-house seawater standard that was intercalibrated against known solid materials (NBS-19, IAEA-C2, and NBS-20). Intercalibration was performed on the same Picarro instrument using an Automate-Liaison front-end unit. Total alkalinity was determined using an open-system Gran titration on 5-mL samples in triplicate, using a Metrohm 805 Dosimat and a robotic Titrosampler, calibrated against seawater Certified Reference Materials.
- Imported the first sheet of the original file "EN669_CTD_Bottle_BCODMO.xlsx" from into the BCO-DMO system.
- Removed the empty column (column M in Excel file).
- Renamed fields to comply with BCO-DMO naming conventions.
- Created the ISO_DateTime_UTC column by converting the julian date (TimeJ) column to ISO 8601 format.
- Saved the final file as "915709_v1_en669_bottle.csv".
| File |
|---|
915709_v1_en669_bottle.csv (Comma Separated Values (.csv), 45.55 KB) MD5:01c3141137b3499bdd17bf0a30a734cb Primary data file for dataset ID 915709, version 1 |
Relationship Description: A complementary dataset from the same year in the same region.
| Parameter | Description | Units |
| CTD_Cast | Cast number from cruise EN669 | unitless |
| Niskin | Bottle number on Niskin rosette | unitless |
| PotTemp | Potential temperature used in carbsys calculations | degrees Celsius |
| Sal | Salinity value used in carbsys calculations | unitless |
| Depthm | Depth used in carbsys calculations | meters (m) |
| DIC_Bottle | Niskin bottle number from which DIC water sample was taken | unitless |
| DICumolkg | Dissolved inorganic carbon | micromoles per kilogram seawater |
| d13Cpermil | delta carbon isotope value vs PDB | permille vs PDB |
| talkumolkg | Total alkalinity | micromoles per kilogram seawater |
| DICsd | 1 standard deviation, dissolved inorganic carbon measurement | micromoles per kilogram seawater |
| d13Csd | 1 standard deviation, delta carbon isotope measurement | permille vs PDB |
| talksd | 1 standard deviation, total alkalinity measurement | micromoles per kilogram seawater |
| Scan | Scan number (24 scans/second) | unitless |
| TimeJ | Julian time | days |
| TimeS | Duration (seconds) | seconds |
| PrDM | Pressure digiquartz (meters) | meters (m) |
| T090C | Primary temperature (degrees C) | degrees Celsius |
| T190C | Secondary temperature (degrees C) | degrees Celsius |
| T2_T190C | Difference between primary and secondary temperature | degrees Celsius |
| C0S_m | Primary conductivity S/m | Siemens/meter |
| C1S_m | Secondary conductivity (S/m) | Siemens/meter |
| C2_C1S_m | Difference between primary and secondary conductivity | Siemens/meter |
| V0 | Voltage of transmissometer | volts (V) |
| CStarAt0 | Attenuation (1/m) | 1/meter |
| CStarTr0 | Beam transmission (%) | percent |
| V1 | Voltage of fluorometer | volts (V) |
| FlECO_AFL | Flourometer Eco Chl a (mg/m3) | milligrams per cubic meter |
| V2 | Altimeter voltage | volts (V) |
| AltM | Altimeter (m) | meters (m) |
| V3 | Par sensor voltage | volts (V) |
| V4 | Primary oxygen voltage | volts (V) |
| Sbeox0V | Primary oxygen voltage | volts (V) |
| V5 | Secondary oxygen voltage | volts (V) |
| Sbeox1V | Secondary oxygen voltage | volts (V) |
| Par | Photosynthetically available radiation - on the ctd (umol photons/m2/s) | micromoles photons per meter-squared per second |
| Cpar | Corrected PAR (umol photons/m2/s) | micromoles photons per meter-squared per second |
| Spar | Surface photosynthetically available radiation - on the ship (umol photons/m2/s) | micromoles photons per meter-squared per second |
| Pumps | on or off (on=1) | unitless |
| Latitude | latitude in degrees north | decimal degrees |
| Longitude | longitude in degrees east | decimal degrees |
| DepSM | Depth saltwater meters | meters (m) |
| Sal00 | Salinity - calc -- using primary T and primary cond. | unitless |
| Sal11 | Salinity - calc -- using secondary T and secondary cond. | unitless |
| Sigma_E00 | Density - calc -- using primary T and primary cond. | kilograms per cubic meter (minus 1000) |
| Sigma_E11 | Density - calc -- using secondary T and secondary cond. | kilograms per cubic meter (minus 1000) |
| Sbox0Mm_Kg | Seabird oxygen (umol/kg) primary sensor | micromoles per kilogram seawater |
| Sbox1Mm_Kg | Seabird oxygen (umol/kg) secondary sensor | micromoles per kilogram seawater |
| OxsolMm_Kg | Oxygen saturation (Garcia and Gordon, µmol/kg) | micromoles per kilogram seawater |
| OxsatMm_Kg | Oxygen (Weiss, umol/kg) | micromoles per kilogram seawater |
| Potemp090C | Potential temperature (ITS90, degrees C) primary | degrees Celsius |
| Potemp190C | Potential temperature (ITS90, degrees C) secondary | degrees Celsius |
| SvCM | Sound velocity (Chen-Millero, m/s) primary | meters per second |
| SvCM1 | Sound velocity (Chen-Millero, m/s) secondary | meters per second |
| Dz_dtM | Descent rate (m/s) | meters per second |
| Gpa | Geopotential anomaly (J/kg) | Joules per kilogram |
| Nbin | Number of bins in a row | unitless |
| Flag | Quality control; 0 = ok, 1 = problem | unitless |
| ISO_DateTime_UTC | Date and time (UTC) in ISO 8601 format | unitless |
| Dataset-specific Instrument Name | Niskin bottles |
| Generic Instrument Name | Niskin bottle |
| Dataset-specific Description | Water samples were collected using Niskin bottles on the CTD rosette. |
| 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 | SeaBird SBE-911+ |
| Generic Instrument Name | CTD Sea-Bird SBE 911plus |
| Dataset-specific Description | Water samples were collected using Niskin bottles on the CTD rosette. Equipment included a Seabird Scientific SBE9plus CTD equipped with a transmissometer, oxygen, and fluorescence sensors. |
| Generic Instrument Description | The Sea-Bird SBE 911 plus is a type of CTD instrument package for continuous measurement of conductivity, temperature and pressure. The SBE 911 plus includes the SBE 9plus Underwater Unit and the SBE 11plus Deck Unit (for real-time readout using conductive wire) for deployment from a vessel. The combination of the SBE 9 plus and SBE 11 plus is called a SBE 911 plus. The SBE 9 plus uses Sea-Bird's standard modular temperature and conductivity sensors (SBE 3 plus and SBE 4). The SBE 9 plus CTD can be configured with up to eight auxiliary sensors to measure other parameters including dissolved oxygen, pH, turbidity, fluorescence, light (PAR), light transmission, etc.). more information from Sea-Bird Electronics |
| Dataset-specific Instrument Name | Titrosampler |
| Generic Instrument Name | Automatic titrator |
| Dataset-specific Description | Total alkalinity was determined using an open-system Gran titration on 5-mL samples in triplicate, using a Metrohm 805 Dosimat and a robotic Titrosampler, calibrated against seawater Certified Reference Materials. |
| Generic Instrument Description | Instruments that incrementally add quantified aliquots of a reagent to a sample until the end-point of a chemical reaction is reached. |
| Dataset-specific Instrument Name | SEAL Analytical AA3 HR |
| Generic Instrument Name | Seal Analytical AutoAnalyser 3HR |
| Dataset-specific Description | Nutrients were determined at the WHOI Nutrient Analytical Facility on a SEAL Analytical AA3 HR following established procedures. |
| Generic Instrument Description | A fully automated Segmented Flow Analysis (SFA) system, ideal for water and seawater analysis. It comprises a modular system which integrates an autosampler, peristaltic pump, chemistry manifold and detector. The sample and reagents are pumped continuously through the chemistry manifold, and air bubbles are introduced at regular intervals forming reaction segments which are mixed using glass coils. The AA3 uses segmented flow analysis principles to reduce inter-sample dispersion, and can analyse up to 100 samples per hour using stable LED light sources. |
| Dataset-specific Instrument Name | Picarro G-2121i Cavity Ringdown Spectrometer |
| Generic Instrument Name | Cavity enhanced absorption spectrometers |
| Dataset-specific Description | DIC-d13C was determined using an Apollo AS-D1 DIC and d13C-DIC analyzer unit, connected to a Picarro G-2121i Cavity Ringdown Spectrometer. |
| Generic Instrument Description | Instruments that illuminate a sample inside an optical cavity, typically using laser light, and measure the concentration or amount of a species in gas phase by absorption spectroscopy. Techniques include cavity ring-down spectroscopy (CRDS) and integrated cavity output spectroscopy (ICOS). |
| Dataset-specific Instrument Name | Apollo AS-D1 analyzer |
| Generic Instrument Name | Apollo AS-D1 DIC and d13C-DIC Analyzer |
| Dataset-specific Description | DIC-d13C was determined using an Apollo AS-D1 DIC and d13C-DIC analyzer unit, connected to a Picarro G-2121i Cavity Ringdown Spectrometer. |
| Generic Instrument Description | The AS-D1 is an instrument designed to prepare natural water samples for Dissolved Inorganic Carbon (DIC) and delta13C analysis and provide the user with the analyses outputs. It has features that are specifically useful for seawater and coastal water samples. The instrument provides the user with DIC values (micromol per kg) and the delta13C content of the DIC (per mille). It consists of a digital syringe pump for delivery of reagent and samples, a mass flow controller to regulate flow rate, a CO2 stripping reactor, and an electronic cooling system to remove moisture. The AS-D1 does not measure the sample but is designed to send the gas to a different analyzer. This second instrument then sends the measurements back to the AS-D1 after analysis. The AS-D1 then calculates the desired DIC and delta13C outputs. This instrument is designed for automatic sampling from multiple bottles. It can be used in laboratories on shore or at sea.
The instrument was created to be paired with the Picarro G-2131i Carbon Isotope Analyser, however, other models that measure the isotopic ratio of CO2 may be compatible. The precision is +/- 0.1 % for DIC of seawater and +/- 0.07 % for DIC-delta13C. Sample volume is 1-7 milliliters per analysis, and sample time is under 12 minutes.
Additional information from the manufacturer is available at: https://apolloscitech.com/dicdelta.html |
| Dataset-specific Instrument Name | Metrohm 805 Dosimat |
| Generic Instrument Name | Metrohm 805 Dosimat |
| Dataset-specific Description | Total alkalinity was determined using an open-system Gran titration on 5-mL samples in triplicate, using a Metrohm 805 Dosimat and a robotic Titrosampler, calibrated against seawater Certified Reference Materials. |
| Generic Instrument Description | The Metrohm 805 Dosimat is a dispensing instrument for titrating and dosing operations in the laboratory. The 805 Dosimat is controlled by Touch control or PC control software. The instrument controls the dosing of liquids, which are attached via an exchange unit. Metrohm recommends using the Metrohm 806 Exchange units which come with 1, 5, 10, 20, or 50 milliliter (mL) dosing cylinders. The instrument can read and overwrite data from the exchange unit. It has a resolution of 20,000 steps per cylinder volume and a dosing/filling time of 18 seconds.
The 805 Dosimat and the corresponding 806 Exchange Unit are suitable as a buret not only for simply dosing auxiliary solutions but also for titrations. Additional information is available from the instrument manufacturer: https://www.metrohm.com/en_au/products/2/8050/28050010.html |
EN669
| Website | |
| Platform | R/V Endeavor |
| Start Date | 2021-08-03 |
| End Date | 2021-08-12 |
| Description | More information is available in R2R: https://www.rvdata.us/search/cruise/EN669
Start/End: Narragansett, Rhode Island |
CAREER: Gulf of Maine Temperature Trends and Variability from the early Holocene to the Present (GoM Temperature Trends)
NSF Award Abstract:
The Gulf of Maine supports a highly productive marine ecosystem extending from Cape Cod to Nova Scotia. Ocean temperatures in this region are sensitive to changes in the relative influx of colder currents from the north and warmer currents from the south, which are ultimately linked to the greater regional and global ocean-atmosphere circulation. From 2004 to 2013, the Gulf of Maine warmed faster than 99% of the world's oceans, but the processes driving recent temperature change here are not fully understood. A deeper understanding of oceanographic trends on time scales beyond instrumental records (older than ~100 years) can elucidate the causes of change, determine whether abrupt changes have happened in the past, and shed light on environmental impacts on past coastal communities. This project brings together a multi-disciplinary team of researchers and Native American students in New England, who will conduct a 10-day research expedition in the Gulf and delve into the region's past using geochemical evidence buried in ancient marine sediments. Results and research experiences of students will be shared with the broader community via development of an innovative multi-media online storytelling environment and through partnership with local schools. The project has the potential to enhance long-term environmental prediction and planning in an area where human populations and ocean ecosystems have been interlinked for millennia.
Long-term records of ocean temperature and seawater oxygen isotope composition (d18O) will be reconstructed from the magnesium to calcium ratio (Mg/Ca) and d18O of fossil foraminiferal calcite derived from a suite of sediment cores from the Gulf of Maine and Scotian Shelf and Slope. High-resolution (~100 to 200-year interval) records will extend from the start of the Holocene ~11,600 years ago to the present, providing insight into long-term temperature trends as well as any abrupt changes. In addition to traditional whole-shell geochemical analysis, micro-analysis of individual foraminiferal specimens will be conducted to provide complementary data for assessing environmental variability. A research cruise in the Gulf of Maine will provide sediment-core and plankton-tow material as well as hydrographic data for refinement and regional calibration of the geochemical proxies. One key goal is to test and extend the Mg/Ca-temperature calibration for a common high-latitude foraminifer species, Neogloboquadrina incompta. In parallel with paleoceanographic research, artifacts from coastal archaeological sites will be radiocarbon-dated to refine the chronology of fishing practices in the region. In particular, the beginning and end of intensive sword-fishing in coastal communities will be re-dated and reassessed in light of new paleotemperature data. All work will be carried out by a team of high school, undergraduate, and graduate students who will gain both technical and communications training in partnership with the Wabanaki Center and the New Media and Internet Technologies Lab at the University of Maine. In addition to developing online narratives that can be widely shared, high school students will practice presenting their research verbally to different groups, including at national meetings. A diverse team of women and men, including a member of the Penobscot Nation, will collaborate to guide and mentor students through the scientific process and to help them develop a voice that can effectively reach diverse audiences.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
| Funding Source | Award |
|---|---|
| NSF Division of Ocean Sciences (NSF OCE) |
[ table of contents | back to top ]