The new gliders were launched at the same time following several months of preparations for their nine-month deployment. Using multiple gliders simultaneously allows researchers to acquire very detailed information needed to understand the complex workings of the ocean, which is affected by seasonal wind and weather, as well as longer-term climate changes.
BIOS’ newest gliders made their research debut in late September when they slipped into waters near St. David’s Head and headed to a predetermined destination 50 miles offshore Bermuda. For the next nine months, the duo known as Jack and Minnie will use their payload of scientific sensors to record daily changes in water chemistry and currents, as the summer cap of warm surface waters is mixed and replaced with cooler, nutrient-rich waters from below, and tiny microbes and phytoplankton respond to the changing conditions.
Late winter to early spring brings a “bloom” of phytoplankton and a consequent explosion of marine life in the Sargasso Sea. Measurements of temperature, oxygen, salinity, nutrients, chlorophyll, and currents, sent back several times daily via satellite to scientists on shore, will provide detailed insights about the interplay between weather and ocean currents, and how these influence the cycling of nutrients, oxygen, and carbon at the core of the marine food web.
Marine technician David Aragon of Rutgers University and scientist Ruth Curry, who heads the glider program at BIOS, made adjustments to the glider named Minnie before deploying the vehicle offshore Bermuda in September. Minnie, and a companion glider named Jack, will spend the next nine months collecting data about ocean processes that support the marine food web.
Phytoplankton use sunlight to transform nutrients and carbon dioxide into oxygen, which produces half the air we breathe, and draws carbon dioxide, a potent greenhouse gas, out of the atmosphere. The phytoplankton themselves are food for zooplankton and larger marine organisms, while bacteria and other marine microbes use the oxygen and organic material to recycle and replace nutrients in the water. Interactions between ocean currents and wind can enhance or suppress the delivery of nutrients from deep waters to the upper sunlit layers, where phytoplankton live and kick start the entire food web.
The 6-foot-long gliders continually dive to a depth of 3,000 feet and climb back to the surface in a saw-tooth shaped pattern. Operating in tandem, Jack and Minnie will circle around the site of the long-running Bermuda Atlantic Time Series (BATS), which for 27 years has built a month-by-month picture of the cycling of carbon, oxygen, nutrients, and other ocean properties in the Sargasso Sea.
Making eight dives each day, the gliders will greatly enhance the amount of information being collected, which, combined with the BATS measurements, will fill in key pieces missing from our understanding of these complex marine processes.
“We hope to see, in exquisite detail, exactly what is going on under the surface from late summer to late spring,” said physical oceanographer Ruth Curry, who oversees the glider program at BIOS.
Like gliders used by other research institutions, BIOS gliders are being used for a variety of applications. In October 2014, BIOS’ first autonomous glider, Anna, was deployed prior to Hurricane Gonzalo for a rare look at what happens in the ocean underneath these powerful storms. Gliders are also being used to help predict hurricane intensity by providing information about subsurface ocean temperatures, on which tropical storms feed.
The 6-foot-long gliders dive to a depth of 3,000 feet. Several times each day, the gliders resurface and send data via satellite to scientists on shore. They also receive instructions about any changes in their missions.
The BIOS gliders are equipped with a variety of sensors: a CTD (for conductivity, temperature, and depth) and optical sensors that measure oxygen, fluorescence and backscatter, an indicator of the abundance of microscopic marine organisms in the water.
Operating as a team, each glider also has specialized capabilities related to the scientific mission. Jack has been outfitted with an Acoustic Doppler Current Profiler, or ADCP, which provides detailed profiles of ocean currents. Minnie is equipped with a state-of-the-art nitrate sensor to measure nutrients.
Together these measurements will enable researchers to address long-standing questions about biological productivity that supports the entire marine food web, and the ocean’s role in drawing down carbon dioxide from the atmosphere that affects the rate of greenhouse warming.