Dataset: 32Si and 14C Production - Profiles - from DY131

Name: Depth profiles in the euphotic zone of nitrate, silicate, and phosphate concentrations and profiles of silicic acid uptake rates from EXPORTS cruise DY131 in the North Atlantic during May 2021
Published: 2023-04-12
Keywords: oceans

Cite This Dataset

DOI:10.26008/1912/bco-dmo.893293.1

Spatial Extent: N:49.2341 E:-14.5095 S:48.7816 W:-14.9764

Temporal Extent: 2021-05-06 - 2021-05-27

Project:

Collaborative Research: Diatoms, Food Webs and Carbon Export - Leveraging NASA EXPORTS to Test the Role of Diatom Physiology in the Biological Carbon Pump (Diatoms and carbon export)

Program:

EXport Processes in the Ocean from Remote Sensing (EXPORTS)

Principal Investigator:

Mark A. Brzezinski (University of California-Santa Barbara, UCSB-MSI)

Co-Principal Investigator:

Kristen Nicolle Buck (University of South Florida, USF)

Bethany D. Jenkins (University of Rhode Island, URI)

Contact:

Janice L. Jones (University of California-Santa Barbara, UCSB-MSI)

BCO-DMO Data Manager:

Shannon Rauch (Woods Hole Oceanographic Institution, WHOI BCO-DMO)

Version:

Version Date:

2023-04-12

Restricted:

Validated:

Yes

Current State:

Final no updates expected

Depth profiles in the euphotic zone of nitrate, silicate, and phosphate concentrations and profiles of silicic acid uptake rates from EXPORTS cruise DY131 in the North Atlantic during May 2021

Abstract:

This dataset includes depth profiles in the euphotic zone of nutrient (nitrate, silicate, phosphate) concentrations and profiles of silicic acid uptake rates from seawater samples collected on EXPORTS cruise DY131 during May 2021. This research focuses on the vertical export of the carbon associated with a major group of phytoplankton, the diatoms in the North Atlantic near the Porcupine Abyssal Plain. The major objective is to understand how diatom community composition and the prevailing nutrient conditions create taxonomic differences in metabolic state that combine to direct diatom taxa to different carbon export pathways. The focus is on diatoms, given their large contribution to global marine primary productivity and carbon export which translates into a significant contribution to the biogeochemical cycling of carbon (C), nitrogen (N), phosphorus (P), iron (Fe) and silicon (Si). It is hypothesized that the type and degree of diatom physiological stress are vital aspects of ecosystem state that drive export. To test this hypothesis, combined investigator expertise in phytoplankton physiology, genomics, and trace element chemistry is used to assess the rates of nutrient use and the genetic composition and response of diatom communities, with measurements of silicon and iron stress to evaluate stress as a predictor of the path of diatom carbon export. The EXPORTS field campaign in the North Atlantic sampled a retentive eddy over nearly a month. At the beginning of the cruise, nitrate was abundant while silicic acid was nearly undetectable. Such low dissolved Si concentrations significantly limit diatom silicification resulting in diatoms with reduced mineral ballast and low Si:C and Si:N ratios that would reduce sinking rates and competition for Si can alter diatom taxonomic composition. Both factors can the path cells follow through the food web ultimately altering diatom carbon export. Within each ecosystem state examined in the EXPORTS program, nutrient biogeochemistry, diatom and phytoplankton community structure, and global diatom gene expression patterns (metatranscriptomics) are characterized in the ocean. Nutrient amendment experiments with tracer addition (14C, 32Si) are used to quantify the level of Si, N, and Fe stress being experienced by the phytoplankton and to contextualize taxa-specific metatranscriptome responses for resolving gene expression profiles in the in situ communities.

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Archival Copy

Version Date	Archive	Persistent Identifier (PID)	Date PID Issued
2023-04-12	Marine Biological Laboratory/Woods Hole Oceanographic Institution Library (MBLWHOI DLA)	10.26008/1912/bco-dmo.893293.1	2023-04-13

Description

Depth profiles in the euphotic zone of nutrient (nitrate, silicate, phosphate) concentrations, profiles of silicic acid uptake rates, and assessment of limitation by Si, N, and Fe on both silicic acid uptake and carbon fixation.

See the related dataset (https://www.bco-dmo.org/dataset/893324) for the data from the nutrient limitation assessments.

Methods & Sampling

Seawater samples were collected using an epoxy coated CTD-rosette mounted with Go-Flo samplers and a Sea-Bird Electronics CTD (SBE9plus). Go-Flo bottles were transferred to a trace metal clean van for subsampling into polypropylene tubes (nutrients), polypropylene bottle (biogenic silica and particulate carbon and nitrogen) or TM acid-cleaned polycarbonate incubation bottles (Si-32 & C-14 incubation experiments).

Nutrient samples were filtered through 0.2 micrometer (μm) polycarbonate filters and frozen at -20° Celsius (C). Samples for biogenic silica concentrations were size fractionated by serial filtration through 5 μm and 0.6 μm polycarbonate filters Filters were stored frozen at -20°C. Particulate organic carbon and nitrogen were measured on samples from experiments examining the effect of added Fe and Si on carbon fixation. These samples were filtered through precombusted GFF filters placed in glass scintillation vials and frozen at -20°C.

Samples for silicic acid uptake profiles were spiked with the radioisotope Si-32. Nutrient limitation assays were performed on pairs of samples where the rate of silicic acid uptake (Si-32) or carbon fixation (C-14 in paired light/dark bottles) were determined in unaltered controlled samples and in samples augmented with either silicic acid (20 μM), nitrate (20 μM) or iron chloride (1 nanomolar (nM)). All samples were incubated on deck in simulated in situ incubators cooled with flowing surface seawater for 24 hours. Profiles sampled six depths from near surface to the 1% light level. Nutrient limitation assays were performed at the 40% and 10% light levels.

Particles from incubated samples were size fractionated by serial filtration through 5 μm and 0.6 μm 25-millimeter (mm) polycarbonate filters. For C-14 incubations, total radioactivity in each sample was determined by sampling 100 μl of sample seawater prior to filtration. Filters from Si-32 incubations were placed on plastic planchettes and dried before covering with mylar film and stored for analysis ashore using low-level beta counters (Riso Inc). Filters from C-14 incubations were acidified in glass scintillation vials, scintillation cocktail (Ultima Gold XR) was added followed by liquid scintillation counting. Total radioactivity samples received 100 μL of b-phenethylamine and 5 mL of scintillation cocktail prior to analysis at sea using a Tri-Carb 3110TR scintillation counter.

Biogenic silica concentrations were determined by NaOH digestion followed by colorimetric analysis of the resulting dissolved Si. Particulate organic carbon and nitrogen samples were analyzed by Dumas combustion. Nutrient concentrations were determined by flow injection using a Lachat Instruments QuikChem 8500 Series 2 anayzer.

For more information, see the Protocol documents attached as Supplemental Files and https://msi.ucsb.edu/facilities-services/analytical-lab/services.

Data Processing Description

Silicon uptake was calculated as the product of the fraction of total Si-32 radioactivity taken up and the ambient silicic acid concertation. Rates of primary production were calculated as the product of the fraction of total C-14 radioactivity taken up and a DIC value of 2132 micromoles per kilogram (μmol kg-1) correcting for isotope discrimination (x 1.05).

Nutrient concentrations were adjusted using certified JAMSTEC CRMs.

BCO-DMO Processing:
- removed "~" as a missing data value (replaced by blanks/empty values);
- renamed fields to comply with BCO-DMO naming conventions;
- created ISO 8601 date-time field and removed original date and column columns.

Data Files

File
exports_dy131_profiles.csv (Comma Separated Values (.csv), 8.22 KB) MD5:0280d85605761c4e3fad6294a5d5acf0 Primary data file for dataset ID 893293

Supplemental Files

File
Brzezinski Lab 14C Primary Production Protocols filename: 14C_Primary_Production.pdf (Portable Document Format (.pdf), 287.04 KB) MD5:98b17db0d497db8baef492b6f642dd05 Brzezinski Lab 14C Primary Production Protocols
Brzezinski Lab 32Si Sample Processing Protocols filename: 32Si_Sample_Processing.pdf (Portable Document Format (.pdf), 218.87 KB) MD5:a4958e873573df157b6a20b4a2028c35 Brzezinski Lab 32Si Sample Processing Protocols
Brzezinski Lab bSi Protocols filename: bSi_Protocol.pdf (Portable Document Format (.pdf), 214.54 KB) MD5:32afa2b8fe4d9ce0cde6b78bc9687248 Brzezinski Lab bSi Protocols
Brzezinski Lab Chl Filtration Protocols filename: Brzezinski_Lab_Chl_filtration_protocols.pdf (Portable Document Format (.pdf), 260.99 KB) MD5:03fbf36e45c7f1969b00f4dc6e095b3a Brzezinski Lab Discrete Chlorophyll Filtration Procedure
Brzezinski Lab Chl Reading Protocols filename: Brzezinski_Lab_Chl_reading_protocols.pdf (Portable Document Format (.pdf), 204.98 KB) MD5:e7444ee1719794046e34ac15e92663ea Brzezinski Lab Chlorophyll Sample Processing Protocols

More Information about this dataset

Funding Sources

Funding Source	Award Number
NSF Division of Ocean Sciences	OCE-1756442

Deployments

Deployment	Synonyms	Start Date	Platform	Investigator
DY131	EXPORTS 2021 North Atlantic Deployment	2021-05-01	RRS Discovery	Craig M. Lee (Chief Scientist)	data info

Instruments

CTD Sea-Bird

Supplied Name: Sea-Bird Electronics CTD (SBE9plus)

Supplied Description:

Instrument Type

Generic Name: CTD Sea-Bird

Community Identifier: http://vocab.nerc.ac.uk/collection/L05/current/130/

Generic Description:

Conductivity, Temperature, Depth (CTD) sensor package from SeaBird Electronics, no specific unit identified. This instrument designation is used when specific make and model are not known. See also other SeaBird instruments listed under CTD. More information from Sea-Bird Electronics.

GO-FLO Bottle

Supplied Name: Go-Flo samplers

Supplied Description:

Instrument Type

Generic Name: GO-FLO Bottle

Acronym: GO-FLO

Community Identifier: http://vocab.nerc.ac.uk/collection/L05/current/30/

Generic Description:

GO-FLO bottle cast used to collect water samples for pigment, nutrient, plankton, etc. The GO-FLO sampling bottle is specially designed to avoid sample contamination at the surface, internal spring contamination, loss of sample on deck (internal seals), and exchange of water from different depths.

Lachat QuikChem 8500 flow injection analysis system

Supplied Name: Lachat Instruments QuikChem 8500 Series 2 analyzer

Supplied Description:

Instrument Type

Generic Name: Lachat QuikChem 8500 flow injection analysis system

Acronym: QuikChem 8500

Generic Description:

The Lachat QuikChem 8500 Series 2 Flow Injection Analysis System features high sample throughput and simple, but rapid, method changeover. The QuikChem 8500 Series 2 system maximises productivity in determining ionic species in a variety of sample types, from sub-ppb to percent concentrations. Analysis takes 20 to 60 seconds, with a sample throughput of 60 to 120 samples per hour.

PerkinElmer Tri-Carb 3110TR low activity liquid scintillation analyzer

Supplied Name: Tri-Carb 3110TR

Supplied Description:

Instrument Type

Generic Name: PerkinElmer Tri-Carb 3110TR low activity liquid scintillation analyzer

Acronym: Tri-Carb 3110TR

Generic Description:

The PerkinElmer Tri-Carb 3110TR is a benchtop liquid scintillation analyzer for detecting small amounts of alpha, beta, and gamma radioactivity. It features a Multichannel Analyzer with an effective resolution of 1/10 keV and an extended dynamic quench range. Sample capacity is either 408 standard 20 mL vials, or 720 small 4 or 7 mL vials. The instrument includes a barium-133 low-energy external standard source centered under the sample vial which eliminates the effects of volume variations. It has an energy range of 0-2000 keV and an operating ambient temperature range of 15-35 degrees Celsius.

Parameters

Date and time formats are described in python strftime() syntax.

Supplied Name	Supplied description	Supplied Units	Standard Name
Cruise	cruise during which sample was collected	unitless	cruise_id
ISO_DateTime_UTC	date and time (UTC) of sample collection in ISO 8601 format Format: %Y-%m-%dT%H:%M:%SZ	unitless	ISO_DateTime_UTC
Event	event number from R2R event log	unitless	event
Activity	which instrument was used for sample collection	unitless	instrument
Station	station identifier	unitless	station
Cast	CTD or TM cast number	unitless	cast
Latitude	latitude (positive values = North; negative values = South)	decimal degrees	lat
Longitude	longitude (positive values = East; negative values = West)	decimal degrees	lon
Target_Depth	target depth for sample collection	meters (m)	depth_n
Actual_Depth	actual depth for sample collection	meters (m)	depth_n
Light_Level	percent light level (PAR sensor)	unitless (percent)	PAR
Phosphate	dissolved phosphate (PO4) concentration in micromoles; analyzed in UCSB MSI Analytical lab	millimoles per cubic meter (mmol m^3)	PO4
Phosphate_Flag	data flag: 1 = good; 2 = manual badflag; 3 = below detection limit; 9 = missing; as per Norm Nelson and his Seabass submission	unitless	q_flag
Silicate	silicic acid concentration (SiO4) in micromoles (also known as dissolved silicon concentration or dSi)	millimoles per cubic meter (mmol m^3)	Silicate
Silicate_Flag	data flag: 1 = good; 2 = manual badflag; 3 = below detection limit; 9 = missing; as per Norm Nelson and his Seabass submission	unitless	q_flag
Nitrite	dissolved nitrite (NO2) concentration in micromoles; analyzed in UCSB MSI Analytical lab	millimoles per cubic meter (mmol m^3)	NO2
Nitrite_Flag	data flag: 1 = good; 2 = manual badflag; 3 = below detection limit; 9 = missing; as per Norm Nelson and his Seabass submission	unitless	q_flag
Nitrate_and_Nitrite	dissolved nitrate+nitrite concentration in micromoles; analyzed in UCSB MSI Analytical lab	millimoles per cubic meter (mmol m^3)	NO3_NO2
Nitrate_and_Nitrite_Flag	data flag: 1 = good; 2 = manual badflag; 3 = below detection limit; 9 = missing; as per Norm Nelson and his Seabass submission	unitless	q_flag
Blank_Corrected_POC	particulate organic carbon (POC) in micromoles; analyzed in UCSB MSI Analytical lab	milligrams per cubic meter (mg m^3)	POC
POC_Flag	data flag: 1 = good; 2 = manual badflag; 3 = below detection limit; 9 = missing; as per Norm Nelson and his Seabass submission	unitless	q_flag
Blank_Corrected_PON	particulate organic nitrogen (PON); analyzed in UCSB MSI Analytical lab	milligrams per cubic meter (mg m^3)	PON
PON_Flag	data flag: 1 = good; 2 = manual badflag; 3 = below detection limit; 9 = missing; as per Norm Nelson and his Seabass submission	unitless	q_flag
chl_a_0_6um_to_5um	chlorophyll a in micrograms per liter for the 0.6 to 5 micrometer (um) size fraction	micrograms per cubic meter (ug m^3)	chl_a
chl_a_gt_5um	chlorophyll a in micrograms per litre for the size fraction of 5 micrometers (um) and greater	micrograms per cubic meter (ug m^3)	chl_a
bSi_0_6um_to_5um	particulate biogenic silica in nanomoles Si per litre for the 0.6 to 5 micrometer (um) size fraction	nanomoles Si per liter (nmol Si L^1)	Si_bio
bSi_gt_5um	particulate biogenic silica in nanomoles Si per litre for the size fraction of 5 micrometers (um) and greater	nanomoles Si per liter (nmol Si L^1)	Si_bio
rate_32Si_uptake_24hr_0_6umfilt_5umprefilt	size fractionated silicic acid 32Si uptake for the 0.6 to 5 micrometer (um) size fraction	nanomoles Si per liter per day (nmol Si L^1 d^1)	Si_acid
rate_32Si_uptake_specific_24hr_0_6umfilt_5umprefilt	size fractionated specific silicic acid 32Si uptake for the 0.6 to 5 micrometer (um) size fraction	per day (d^1)	Si_acid
rate_32Si_uptake_24hr_gt_5umfilt	size fractionated silicic acid 32Si uptake for the size fraction of 5 micrometers (um) and greater	nanomoles Si per liter per day (nmol Si L^1 d^1)	Si_acid
rate_32Si_uptake_specific_24hr_gt_5umfilt	size fractionated specific silicic acid 32Si uptake for the size fraction of 5 micrometers (um) and greater	per day (d^1)	Si_acid