CTD (temperature, salinity and fluorescence) from bi-weekly vertical profiles in Resurrection Bay, AK from January to March of 2023
Project
| Contributors | Affiliation | Role |
|---|---|---|
| Lenz, Petra H. | University of Hawaiʻi at Mānoa | Principal Investigator |
| Block, Lauren N | University of Hawaiʻi at Mānoa | Scientist, Student |
| York, Amber D. | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Abstract
Samples were collected in Resurrection Bay within the inner basin at RES2.5 (60° 1.5’ N, 149° 21.5’ W; 298 m deep) at approximately biweekly intervals aboard the R/V Nanuq between January 5th and March 24th, 2023. Collection and sample processing are described in detail in Block (2024). Vertical profiles of water temperature, salinity, and fluorescence were measured from 280 m to the surface using a CTD (SBE25 SeaLogger) and WetLabs chlorophyll α fluorometer mounted on an SBE55 rosette with six 4-L Niskin Bottles. Water was collected at discrete depths (surface, 10, 20, 30, 40, 50, 150, and 280 m) for characterization of the phytoplankton and microzooplankton community. Two casts were required to collect all water samples.
CTD data were processed using the SBEDataProcessing-Win32 program. Data processing included filtering, alignment, thermal mass correction, loop edits, and derivation of depth, salinity, and density variables. Data were then averaged at 1 dbar intervals. Data processing was completed according to the SBE Advanced Data Processing Module.
* Sheet 1 of submitted file "NaupProj2023_combinedCTDs_BCODMO.csv" was imported into the BCO-DMO data system for this dataset. Table will appear as Data File: 954156_v1_ctd.csv (along with other download format options).
* Several columns were undescribed in the data submission's "Parameters" section, so those appear as "undocumented" in the column descriptions. The units were listed in the original data file so those appear in the Parameter description section.
Relationship Description: Related data collected as part of the same study published in Block, L. N. (2024, https://hdl.handle.net/10125/108679).
Relationship Description: Related data collected as part of the same study published in Block, L. N. (2024, https://hdl.handle.net/10125/108679).
Relationship Description: Related data collected as part of the same study published in Block, L. N. (2024, https://hdl.handle.net/10125/108679).
| Parameter | Description | Units |
| binned_pressure | Pressure (dbar) binned at 1 dbar intervals | Decibars (dbar) |
| temperature | Water column temperature | Celsius (C) |
| conductivity | Water column conductivity | Siemens per meter (S/m) |
| turbidity | Water column turbidity | Nephelometric Turbidity Unit (NTU) |
| fluorescence | Water column chlorophyll-a fluorescence | Milligrams per cubic meter (mg/m^3) |
| time_elapsed | undocumented. | Seconds (s) |
| scan | undocumented. Units described as "integer" in provided metadata | unitless |
| depth | Depth of CTD in water column. | Meters (m) |
| salinity | Water column salinity | Practical Salinity Units (PSU) |
| sigmaT | Water column density | Kilograms per cubic meter (kg/m^3 ) |
| descent_rate | undocumented. Assumed to be descent rate of an instrument package. | Meters per second (m/s) |
| nbin | undocumented. Assumed to be the commonly preported CTD nbin term referring to the number of data cycles used to compile an average value for a given depth/BIN interval | unitless |
| date | Date (Local time, Alaska Time Zone) in ISO 8601 format yyyy-mm-dd | unitless |
| julianday | Intiger Day of Year (1=Jan 1st) | days |
| cruise | Cruise ID | Unitless |
| station | Station ID | Unitless |
| lat | Station latitude, north is positive | Decimal Degrees |
| lon | Station latitude, west is negative | Decimal Degrees |
| Dataset-specific Instrument Name | WetLabs chlorophyll α fluorometer |
| Generic Instrument Name | Fluorometer |
| Generic Instrument Description | A fluorometer or fluorimeter is a device used to measure parameters of fluorescence: its intensity and wavelength distribution of emission spectrum after excitation by a certain spectrum of light. The instrument is designed to measure the amount of stimulated electromagnetic radiation produced by pulses of electromagnetic radiation emitted into a water sample or in situ. |
| Dataset-specific Instrument Name | |
| Generic Instrument Name | Niskin bottle |
| Dataset-specific Description | SBE55 rosette with 6 4-L Niskin Bottles |
| 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 | |
| Generic Instrument Name | Sea-Bird SBE 25 Sealogger CTD |
| Generic Instrument Description | The Sea-Bird SBE 25 SEALOGGER CTD is battery powered and is typically used to record data in memory, eliminating the need for a large vessel, electrical sea cable, and on-board computer. All SBE 25s can also operate in real-time, transmitting data via an opto-isolated RS-232 serial port. Temperature and conductivity are measured by the SBE 3F Temperature sensor and SBE 4 Conductivity sensor (same as those used on the premium SBE 9plus CTD). The SBE 25 also includes the SBE 5P (plastic) or 5T (titanium) Submersible Pump and TC Duct. The pump-controlled, TC-ducted flow configuration significantly reduces salinity spiking caused by ship heave, and in calm waters allows slower descent rates for improved resolution of water column features. Pressure is measured by the modular SBE 29 Temperature Compensated Strain-Gauge Pressure sensor (available in eight depth ranges to suit the operating depth requirement). The SBE 25's modular design makes it easy to configure in the field for a wide range of auxiliary sensors, including optional dissolved oxygen (SBE 43), pH (SBE 18 or SBE 27), fluorescence, transmissivity, PAR, and optical backscatter sensors. More information from Sea-Bird Electronics: http:www.seabird.com. |
| Dataset-specific Instrument Name | Sea-Bird ECO-NTU Turbidity Sensor |
| Generic Instrument Name | Turbidity Meter |
| Generic Instrument Description | A turbidity meter measures the clarity of a water sample. A beam of light is shown through a water sample. The turbidity, or its converse clarity, is read on a numerical scale. Turbidity determined by this technique is referred to as the nephelometric method from the root meaning "cloudiness". This word is used to form the name of the unit of turbidity, the NTU (Nephelometric Turbidity Unit). The meter reading cannot be used to compare the turbidity of different water samples unless the instrument is calibrated. Description from: http://www.gvsu.edu/wri/education/instructor-s-manual-turbidity-10.htm
(One example is the Orion AQ4500 Turbidimeter) |
Collaborative Research: Zooplankton restarts in a high-latitude marine ecosystem: species-specific recruitment and development in early spring (Zooplankton recruitment)
NSF Award Abstract
Global climate change and associated extreme weather events are increasingly impacting marine communities at all trophic levels and leading to shifts in the timing of life history events. This project is investigating the annual restart of the spring zooplankton community in the Gulf of Alaska in order to determine the timing of species-specific recruitment and growth. Zooplankton are small pelagic animals that are a critical link between microalgae and protozoans and higher levels in the food web including economically important fishes, birds and marine mammals. While their abundances and species composition have been documented over part of the annual cycle between late spring and fall, this project focuses on winter and early spring. The project integrates traditional methods with modern molecular approaches to characterize the diversity, development, feeding and physiology of zooplankton, especially the early developmental stages of copepods (small crustaceans). The goal is to determine which species are there, how many are present and where they are in the water column, and to reveal indicators of their health. Broader impacts include research training for three graduate students and at least four undergraduates in biological oceanography and physiological ecology. Outreach activities are focusing on broadening the public’s understanding of plankton ecology. An illustrated zooplankton guide for the Gulf of Alaska and plankton module for school teachers and students is being produced in collaboration with the Center for Alaskan Coastal Studies. Other plans include sponsorship of nature-drawing workshops on zooplankton and the production of an Art & Science traveling exhibit.
This project is tracking zooplankton population abundances, species composition and developmental stages through the spring restart in a high-latitude fjord in the northern Gulf of Alaska. While the entire zooplankton community is being characterized, the main focus is on the difficult-to-assess early developmental stages of copepods, which dominate the late spring biomass in the region. Three central hypotheses guide the research: 1) high abundances of copepod nauplii are present before any measurable increases in food in surface waters; 2) species diversity increases between winter and spring, with nauplii from large lipid-rich capital-breeding species appearing first, followed by those from income- and hybrid-strategy species and finally nauplii that emerge from dormant eggs; 3) prior to the appearance of food resources, nauplii from capital-breeding species conserve resources by delaying development and entering a state of dormancy in the second and third naupliar stages. The project entails intensive depth-stratified field sampling to characterize the wild community, in combination with laboratory experiments on nauplii to determine their responsiveness to food. The prey are being characterized by measuring chlorophyll a, dietary and prey community DNA sequencing and flow cytometry to establish diversity and abundances. Size-fractionated zooplankton samples are being analyzed using microscopy and community DNA sequencing to ascertain species diversity, developmental stage distribution and abundances. Feeding activity is being measured using dietary DNA sequencing of nauplii followed by comparisons with the prey field. Dormancy in nauplii is being determined by differential gene expression of target genes (RT-qPCR) and high-throughput sequencing of mRNA of individuals (transcriptomics) and community samples (meta-transcriptomics). Short-term and long-term effects of food availability on dormancy, development and growth are being quantified in laboratory experiments. Broader impacts are focused on training of students in interdisciplinary research and state-of-art techniques, and public outreach to introduce plankton ecology to broader audiences.
| Funding Source | Award |
|---|---|
| NSF Office of Polar Programs (formerly NSF PLR) (NSF OPP) | |
| NSF Office of Polar Programs (formerly NSF PLR) (NSF OPP) | |
| NSF Office of Polar Programs (formerly NSF PLR) (NSF OPP) |
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