| Contributors | Affiliation | Role |
|---|---|---|
| Goffredi, Shana | Occidental College | Co-Principal Investigator |
| Orphan, Victoria J. | California Institute of Technology (Caltech) | Co-Principal Investigator |
| Magyar, John S. | California Institute of Technology (Caltech) | Scientist |
| Rauch, Shannon | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Sediment pushcores were collected by DSV Alvin from the R/V Atlantis in May to June 2024 (AT50-24) at Edge Seep (57.4523, -148.0016), Shumagin Seep (54.3016, -157.1969), and Sanak Seep (53.7481, -162.5864). Pushcores were manually sectioned into 1 or 3 centimeter (cm) horizons using plastic rings, and porewaters were extracted using a KC Denmark squeezer. In addition, water samples were collected by Niskin bottle at the seeps using DSV Alvin, and by Niskin bottle from the CTD rosette from R/V Atlantis. Samples for ion chromatography were frozen shipboard and thawed immediately prior to analysis. Measurements were made using a Thermo Dual Dionex Integrion HPIC ion chromatography system with either a 250 millimeter (mm) Dionex IonPac AS19-4um column (anions) with 50 mm guard column or a 250 mm Dionex IonPac CS16-4 micrometer (um) column (cations) with a 50 mm guard column, in the Resnick Water and Environment Laboratory at the California Institute of Technology (Caltech).
100 microliter (uL) samples are diluted 50x in milliQ nanopure water before running. Standard curves are generated using calibration standards diluted similarly to samples, with 100 uL of 500 millimolar (mM) NaCl added to mimic typical seawater sample peak behavior. Analyte peaks are integrated and values are calculated using the standards automatically in the Chromeleon software, with manual QC to ensure regular peak shapes.
- Imported original file "AT50-24_IC_For_BCO_DMO_submission.csv" into the BCO-DMO system.
- Marked "n.a.", "#N/A", "NA", ""NOT_LOGGED", and "NOT_MEASURED" as missing data values (missing data are empty/blank in the final CSV file).
- Renamed fields to comply with BCO-DMO naming conventions.
- Converted "Date_UTC" column to YYYY-MM-DD format.
- Removed the "Time_UTC" column (empty column).
- Saved the final file as "986675_v1_at50-24_ic_data.csv".
| Parameter | Description | Units |
| serial | Internal Orphan Lab identifier (sample serial number) | unitless |
| Fluoride | concentration of fluoride ion | millimolar (mM) |
| Acetate | concentration of acetate ion | millimolar (mM) |
| Formate | concentration of formate ion | millimolar (mM) |
| Chloride | concentration of chloride ion | millimolar (mM) |
| Bromide | concentration of bromide ion | millimolar (mM) |
| Nitrate | concentration of nitrate ion | millimolar (mM) |
| Sulfate | concentration of sulfate ion | millimolar (mM) |
| Thiosulfate | concentration of thiosulfate ion | millimolar (mM) |
| Phosphate | concentration of phosphate ion | millimolar (mM) |
| Lithium | concentration of lithium ion | millimolar (mM) |
| Sodium | concentration of sodium ion | millimolar (mM) |
| Ammonium | concentration of ammonium ion | millimolar (mM) |
| Potassium | concentration of potassium ion | millimolar (mM) |
| Magnesium | concentration of magnesium ion | millimolar (mM) |
| Calcium | concentration of calcium ion | millimolar (mM) |
| perchlorate | concentration of perchlorate ion | millimolar (mM) |
| pH | pH value, measured shipboard | unitless |
| Dive | Dive Number, DSV Alvin | unitless |
| Lat | Latitude | decimal degrees |
| Long | Longitude | decimal degrees |
| Horizon | Depth (cm) in sediment, measured from top of core | centimeters (cm) |
| Date_UTC | Core collection date (UTC) | unitless |
| Depth_m | Core collection time (UTC) | unitless |
| Station | ocean depth in meters at the sampling location | meters (m) |
| Site | name of the sampling site | unitless |
| Sample_Name | the sample name, which is composed of the dive number and the DSV pushcore number | unitless |
| Dataset-specific Instrument Name | DSV Alvin |
| Generic Instrument Name | HOV Alvin |
| Dataset-specific Description | DSV Alvin is owned by the U. S. Navy and operated for NSF by the Woods Hole Oceanographic Institution (WHOI). DSV Alvin is capable of diving to 6500 m (about 4 miles). The R/V Atlantis is the support vessel for Alvin. For a complete description see: https://www.whoi.edu/what-we-do/explore/underwater-vehicles/hov-alvin/ |
| Generic Instrument Description | Human Occupied Vehicle (HOV) Alvin is part of the National Deep Submergence Facility (NDSF). Alvin enables in-situ data collection and observation by two scientists to depths reaching 6,500 meters, during dives lasting up to ten hours.
Commissioned in 1964 as one of the world’s first deep-ocean submersibles, Alvin has remained state-of-the-art as a result of numerous overhauls and upgrades made over its lifetime. The most recent upgrades, begun in 2011 and completed in 2021, saw the installation of a new, larger personnel sphere with a more ergonomic interior; improved visibility and overlapping fields of view; longer bottoms times; new lighting and high-definition imaging systems; improved sensors, data acquisition and download speed. It also doubled the science basket payload, and improved the command-and-control system allowing greater speed, range and maneuverability.
With seven reversible thrusters, it can hover in the water, maneuver over rugged topography, or rest on the sea floor. It can collect data throughout the water column, produce a variety of maps and perform photographic surveys. Alvin also has two robotic arms that can manipulate instruments, obtain samples, and its basket can be reconfigured daily based on the needs of the upcoming dive.
Alvin's depth rating of 6,500m gives researchers in-person access to 99% of the ocean floor. Alvin is a proven and reliable platform capable of diving for up to 30 days in a row before requiring a single scheduled maintenance day. Recent collaborations with autonomous vehicles such as Sentry have proven extremely beneficial, allowing PIs to visit promising sites to collect samples and data in person within hours of their being discovered, and UNOLs driven technological advances have improved the ability for scientific outreach and collaboration via telepresence
Alvin is named for Allyn Vine, a WHOI engineer and geophysicist who helped pioneer deep submergence research and technology.
(from https://www.whoi.edu/what-we-do/explore/underwater-vehicles/hov-alvin/, accessed 2022-09-09) |
| Dataset-specific Instrument Name | Thermo Dual Dionex Integrion HPIC ion chromatography system |
| Generic Instrument Name | Ion Chromatograph |
| Dataset-specific Description | Thermo Dual Dionex Integrion HPIC ion chromatography system with either a 250 mm Dionex IonPac AS19-4um column (anions) with 50 mm guard column or a 250 mm Dionex IonPac CS16-4um column (cations) with a 50 mm guard column, in the Resnick Water and Environment Laboratory at the California Institute of Technology (Caltech). |
| Generic Instrument Description | Ion chromatography is a form of liquid chromatography that measures concentrations of ionic species by separating them based on their interaction with a resin. Ionic species separate differently depending on species type and size. Ion chromatographs are able to measure concentrations of major anions, such as fluoride, chloride, nitrate, nitrite, and sulfate, as well as major cations such as lithium, sodium, ammonium, potassium, calcium, and magnesium in the parts-per-billion (ppb) range. (from http://serc.carleton.edu/microbelife/research_methods/biogeochemical/ic....) |
| Dataset-specific Instrument Name | KC Denmark squeezer |
| Generic Instrument Name | KC Pore-Water Pressing Bench |
| Dataset-specific Description | Porewaters were extracted using a KC Denmark squeezer. |
| Generic Instrument Description | The KC Pore-water pressing bench, made by KC Denmark Research Equipment, allows pore-water extraction of any kind of sediments, from sediments rich in organic material, to sandy sediments. Sediment cores are segmented and placed in the pressing house, which is closed by means of the handle on top of the house. An over-pressure is applied (fed-in) at the reduction valve and the valves of the houses in operation are opened. The resulting compression of the sediment matrix leads to expelling of the pore-water, which is sampled in containers beneath the pressing house. Operation in a glove bag prevents atmospheric contamination with, for example, oxygen, so anaerobic analysis of the pore-water is possible. The standard cylinders are made from black Polyoxymethylene (POM). However, the cylinders and all accessories are also available as AISI 316 stainless steel for special purposes. The pressing bench consists of 5 pressing houses, each 100 ml. They can hold a maximum sample diameter of 40 mm. The instrument has a maximum operating pressure of 4 bar (400 kPa). |
| Dataset-specific Instrument Name | Niskin bottle |
| Generic Instrument Name | Niskin bottle |
| Dataset-specific Description | In addition, water samples were collected by Niskin bottle at the seeps using DSV Alvin, and by Niskin bottle from the CTD rosette from R/V Atlantis. |
| 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. |
| Website | |
| Platform | R/V Atlantis |
| Start Date | 2024-05-16 |
| End Date | 2024-06-07 |
| Description | See more information from R2R: https://www.rvdata.us/search/cruise/AT50-24 |
NSF Award Abstract:
This research examines the role of deep-sea organisms in determining the fate and footprint of methane, a potent greenhouse gas, on Pacific continental margins. The investigators are evaluating the deep ocean methanosphere defined by the microbial communities that consume methane and the animals that directly feed on or form symbioses with methane-consuming microbes. They are also investigating animal communities that gain energy indirectly from methane, as well as those that take advantage of carbonate rocks, the physical manifestation of methane consumption in seafloor sediments. The study of methane seeps in the deep waters of both Alaska (4400-5500 meters) and Southern California (450-1040 meters) is enabling comparisons of the methanosphere under different food-limitation and oxygen regimes. By applying diverse chemical, isotopic, microscopy, and genetic-based analyses to seep microbes and fauna, this study is advancing understanding of the contribution of methane to deep-sea biodiversity and ecosystem function, information that can inform management and conservation actions in US waters. In addition to training for graduate and undergraduate students at their home institutions, the investigators are collaborating with the Alaska Native Science and Engineering Program (ANSEP). They are recruiting Alaskan undergraduates to participate in the research, contributing to ANSEP's online resources that promote interaction between scientists and middle and high school students, and participating in ANSEP's annual residential Career Exploration in Marine Science programs to engage middle school students in learning about deep-sea ecosystems and the variety of career pathways available in marine related fields.
Microbial production and consumption of methane is dynamic and widespread along continental margins, and some animals within deep-sea methane seeps rely on the oxidation and sequestration of methane for nutrition. At the same time, understanding of methane-dependent processes and symbioses in the deep-sea environment is still rudimentary. The goals of this study are to 1) examine the diversity of animals involved in methane-based symbioses and heterotrophic consumption of methane-oxidizing microbes and how these symbioses extend the periphery of seeps, contributing to non-seep, continental slope food webs; and 2) determine whether carbonates on the seep periphery sustain active methanotrophic microbial assemblages, providing a localized food source or chemical fuel for thiotrophic symbioses, via anaerobic oxidation of methane, or free-living, sulfide-oxidizing bacteria consumed by animals. The investigators are addressing these goals by surveying, sampling, and characterizing microbes, water, sediments, carbonates and animals at a deep seep site on the Aleutian Margin and a shallow site off Southern California. Shipboard experiments and laboratory analyses are using molecular, isotopic, geochemical, and radiotracer tools to understand transfer of methane-sourced carbon from aerobic methanotrophs under multiple oxygen levels, pressures, and photosynthetic food inputs. This approach offers a wide lens by which to examine the methane seep footprint, allow reinterpretation of past observations, and identify new scientific areas for future study. Improved characterization of the deep continental margin methanosphere informs climate science, biodiversity conservation, and resource management.
| Funding Source | Award |
|---|---|
| NSF Division of Ocean Sciences (NSF OCE) |