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Sat, Jul

Image of Long Range Autonomous Underwater Vehicles (LRAUVs) in pre-testing before the expedition. The robots were programmed with missions to detect features inside the eddy. When a feature was discovered, the LRAUVs locked in, tracking the feature for days at a time. Image Credit: Elisha M Wood-Charlson / University of Hawai‘i Mānoa. Credit: Elisha M Wood-Charlson/ University of Hawai‘i Mānoa

Science

Schmidt Ocean Institute’s research vessel Falkor arrives with unprecedented detail of microbial communities found in Eddy fields using new underwater vehicles.

In a joint effort between the Simons Collaboration on Ocean Processes and Ecology (SCOPE), the Monterey Bay Aquarium Research Institute (MBARI), and Schmidt Ocean Institute (SOI), several long range autonomous underwater vehicles (LRAUVs) have successfully completed their first voyage in the open ocean, obtaining data on the water column down to 250 meters, while autonomously collecting and archive seawater samples to capture microbial community dynamics in the oceans interior. Since March 10th, 2018, the team on research vessel Falkor has been deploying these new robots programmed with several different mission goals, to provide an unprecedented high-resolution view of open ocean microbes.

EMBED 1 FK180310 Falkor Drone Sunset CTDGabeForemanSchmidt Ocean Institute’s research vessel Falkor completed a month long expedition in Hawaiian waters tracking a cyclonic eddy. While the Long Range Autonomous Vehicles were deployed, researchers on R/V Falkor continued taking samples in more traditional manners, including Conductivity, Temperature, and Depth (CTD) casts. The results of both methods will be compared and studied. Credit: Schmidt Ocean Institute/ Thom Hoffman

Deploying multiple vehicles simultaneously allowed the research team to continuously sample the biologically important deep chlorophyll maximum within a moving eddy field, setting a new record for duration in this type of mission. Open-ocean eddies are swirling masses of water that move slowly across the Pacific Ocean and can have large effects on ocean microbes.

The AUV’s were deployed for the first time in Hawaiian waters and remained in the water collecting data for nearly 100 hours before recovery. Timing is important as it allows for the science team to map the eddy’s structure in 3D while sampling over the course of several daily cycles. This temporal sampling is key, since like people, microbial plankton are believed to synchronize their activities in repetitive daily cycles. The LRAUVs could simultaneously map and sample the oceanographic eddy features in much greater spatial and temporal than would have been possible using other platforms.

EMBED 2 FK180310 WaterSamples Lab180405The collected water samples containing microbial community DNA will be analyzed back in laboratories onshore with genomic studies aimed at understanding the function, activity, and environmental sensitivities of microbial populations that form the foundation of the ocean’s food web. Shown is Ana Maria Cabello from UC Santa Cruz, SCOPE Postdoc. Credit: Schmidt Ocean Institute/ Thom Hoffman

Eddies have been difficult to study because of their natural variability, which means their impact on ocean biology, specifically the microbial communities trapped inside, is not well understood. This cruise focused on a cyclonic eddy, rotating counter clockwise, which results in an uplift of the water column that brings nutrients and organisms from greater depths closer to the surface, and sunlight. This is thought to enhance phytoplankton’s primary productivity and activity in microbial communities that typically reside in deeper, darker waters.

The expedition’s Principal Investigators Dr. Edward DeLong and Dr. David Karl, oceanography professors in UH Mānoa’s School of Ocean and Earth Science and Technology (SOEST), have been studying these microbes for decades. “These new underwater drones will greatly extend our reach to study remote areas and allow us to sample and study oceanographic events and features, even when ships are not available,” said DeLong. “Looking at a day in the life of all these ocean microbes and autonomously tracking them to see what happens on a day-today basis is something that’s never been possible before”.

EMBD 3 FK180310 wirewalker 180312HoffmanTim Burrell (front) and Tara Clemente (back), both with the Simons Collaboration on Ocean Processes and Ecology (SCOPE) operations team, prepare float lines while deploying the Wirewalker instrument. When leaving sensors in the water for weeks at a time researchers need need visible floats and tracking beacons to ensure the instruments can be recovered. Credit: Schmidt Ocean Institute/ Thom Hoffman

Eddies are large (~100 km in diameter) so using autonomous instruments such as LRAUVs, greatly facilitates studies of their variability on relevant spatial and temporal scales. The Falkor’s month long in the water groundtruthing will also help to validate and inform remote observations of eddy structures and evolution that are derived from satellite data. In addition, experiments conducted by the SCOPE scientists onboard the Falkor and in the sea will provide new information on how eddy physical features affect biological processes and ocean productivity over time. The lead scientists expect to derive unique insights into the duration, stability, and influence of eddies on ocean ecosystems; and will improve current ocean biogeochemical models that are critical to understanding the current and future health of the world’s oceans. Additionally, the LRAUV-collected samples containing microbial community DNA will be analyzed back on shore with genomic studies aimed at understanding the function, activity and environmental sensitivities of microbial populations that form the foundation of the ocean’s food web.