New Antarctic research project leverages citizen science to spot environmental changes over time

Northern Arizona University

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High-resolution aerial imagery captured in January 1983 by the U.S. Geological Survey compared to modern high-resolution satellite imagery collected 36 years later.  Since then, the landscape has slowly but noticeably evolved, as can be seen by the rise in lake shoreline.

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Credit: U.S. Geological Survey

Mark Salvatore, an associate professor in NAU’s Department of Astronomy and Planetary Sciences, won a grant from the National Science Foundation to kick off an Antarctic citizen science project.

Working with Lumberjack Ph.D. student Gavin Moriarty, Salvatore will work with ecological researchers in the McMurdo Dry Valleys (MDV) of Antarctica and the crowdsourcing platform Zooniverse to create a citizen science project aimed at measuring environmental change on the continent over the last 70 years. Salvatore said the MDV is one of the most stable landscapes on Earth, and as a result, it’s particularly challenging to study change there.

“Since the 1950s, the U.S. military and the NSF have collected terabytes of aerial photographs over Antarctica for reconnaissance, logistics and scientific purposes,” Salvatore said. “This extensive archive of historical imagery provides a unique opportunity to reconstruct and analyze how cold desert landscapes evolve over decadal to centennial timescales.”

After a short training session, volunteers will be tasked with matching modern satellite images with historical air photos, giving Antarctic researchers a better understanding of how lake level rise, stream evolution and snowfall has changed across the decades. Salvatore said their work could aid researchers for decades to come.

“These contributions will support the creation of a long-term, high-quality dataset and searchable archive that can serve as a foundation for future scientific investigations of Antarctic landscape change,” he said. “In addition to enabling robust data generation, the project emphasizes public engagement through citizen science, open data accessibility and the development of scalable tools that can be applied to similar remote sensing challenges in other polar and remote regions."

Salvatore said citizen scientists should stay tuned for more information about how to get involved.

New study illuminates how diatoms thrive in — and light up — the Southern Ocean

Bigelow Laboratory for Ocean Sciences

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An iceberg spotted near the most southern point of the research cruise’s transect highlights some of the challenges and dangers of gathering data from this part of the ocean.

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Credit: Bigelow Laboratory for Ocean Sciences

An area of the remote Southern Ocean that’s long confused ocean color satellites by reflecting large amounts of turquoise-colored light appears to be full of silica-rich diatoms, according to a new study. Surprisingly, there is also evidence in these polar waters of coccolithophores, a type of marine microalgae with elaborate calcium carbonate shells that plays a critical role in the global carbon cycle.

The study helps answer a longstanding mystery for satellite oceanographers as to what microbes dominate in this part of the ocean that’s proven largely inaccessible, illuminating how the plankton community shifts in response to changing seawater temperature and chemistry. That, in turn, has important implications for the cycling of carbon in the Southern Ocean and the remote sensing tools scientists use to study it.

“This work takes a broad brush to understand the biological and geochemical dynamics of this far-flung body of water in ways that haven’t been previously possible,” said the study’s lead author Barney Balch, a senior research scientist emeritus at Bigelow Laboratory for Ocean Sciences.

The study was published this week in the journal Global Biogeochemical Cycles.

In the early 2000s, Balch and colleagues identified a swath of seawater encircling Antarctica, that became known as the Great Calcite Belt. This area is marked by unusually high levels of particulate inorganic carbon, like calcium carbonate and limestone, that reflects light back to satellites. Scientists eventually confirmed that this was due to the shiny calcium carbonate shells of vast blooms of coccolithophores.

At the same time, though, they identified an area well south of the calcite belt that also appeared unusually bright in satellite images, even though the water was considered too cold for coccolithophores. This mystery has been harder to explain with heavy cloud cover, icebergs, and rough seas making it challenging to monitor this far south with either ships or satellites. Until now.

Researchers sailed aboard the R/V Roger Revelle from Hawaii, down to 60 degrees latitude, taking a brief easterly detour to monitor where water from further south appears to be pinched up into several eddies. Along the transect, the team measured ocean color; calcification and photosynthesis rates; and concentrations of inorganic carbon and silica, two minerals that reflect light and are critical for helping sequester organic carbon in the deep ocean.

“Satellites only see the top several meters of the ocean, but we were able to drill down with multiple measurements at multiple depths,” Balch said. “We’ve never had such a complete suite of integrated measurements through the water column in this part of the ocean.”

The multi-tiered approach — combining biogeochemical measurements, optical data, and even visual counts of microbes with microscopy — enabled the scientists to observe how the plankton community shifts moving south: from dinoflagellates in the warmer, stratified waters of the subtropics, to coccolithophores in the calcite belt, and finally to diatoms in the silica-rich, colder waters south of the Polar Front.

This combination of complementary methods provides a “smoking gun,” Balch said, that the high levels of reflectance scientists have observed in satellite images south of the calcite belt can be explained by frustules. These silica-based structures that diatoms build, resembling microscopic pillboxes, reflect light in much the same way as coccolithophore shells (it takes far more frustules to produce the same optical effect as coccolithophores, though — a testament to how dense their concentration is).

Surprisingly, though, the team also observed small concentrations of inorganic carbon, some amount of calcification happening — a first — and visual evidence of coccolithophores in the far southern waters. This, Balch said, suggests that coccolithophores can survive in colder waters than expected. Perhaps, he said, the eddies coming up from the south even serve as “seed populations,” providing a small but consistent stream of coccolithophores into the Great Calcite Belt.  

The presence of coccolithophores across a wider geographic range than expected could influence how carbon moves through the Southern Ocean, which is considered one of the planet’s most critical sinks for atmospheric carbon. Meanwhile, the dominance of diatoms south of the Polar Front highlights the need to improve the algorithms scientists use to translate satellite data into meaningful predictions of ocean biology. That means potentially combining measurements of other satellite-derived variables to help distinguish between diatoms and coccolithophores in satellite images.

“We’re expanding our view of where coccolithophores live and finally beginning to understand the patterns we see in satellite images of this part of the ocean we rarely get to go to,” Balch said. “There’s nothing like measuring something multiple ways to tell a more complete story.”

In addition to Balch, the interdisciplinary team includes Bigelow Laboratory researchers Dave Drapeau, Bruce Bowler, and Sunny Pinkham, as well as scientists from Woods Hole Oceanographic Institute, Arizona State University, Texas A&M University, and the Bermuda Institute of Ocean Sciences.

Study co-authors Dave Drapeau (left) and Bruce Bowler (right) prepare to launch an probe on a rare sunny day to collect optical data down to the top of the euphotic zone.

Researchers, including study lead author Barney Balch, prepare to launch an probe on a rare sunny day to collect optical data down to the top of the euphotic zone.

Researchers, including study co-authors Bruce Bowler (left) and Sunny Pinkham (with the clipboard), take samples from a CTD rosette that collects water at each station for several variables at multiple depths.

Credit

Bigelow Laboratory for Ocean Sciences

Journal

Global Biogeochemical Cycles

DOI

10.1029/2024GB008457 

Method of Research

Observational study

Subject of Research

Cells

Article Title

Biological, Biogeochemical, Bio-Optical, and Physical Variability of the Southern Ocean Along 150°W and Its Relevance to the Great Calcite Belt

Article Publication Date

4-Aug-2025