A decade ago, scientists on a NASA-sponsored ocean expedition found massive populations of phytoplankton blooming beneath sea ice in the Arctic Ocean. Now scientists using underwater instruments and a NASA satellite have found evidence of potentially significant blooms beneath the sea ice encircling Antarctica. The findings were recently published in the scientific journal Frontiers.
Phytoplankton are to the ocean what grasses are to land: these floating, plant-like organisms soak up sunshine, sponge up mineral nutrients, and create their own food (energy) through photosynthesis. Phytoplankton grow just about anywhere there are open, sunlit patches of ocean. When conditions are right, these collections of microscopic cells can blossom to scales that are visible from space. They are a critical food source for other life in the ocean and a key carbon recycler and disposer for the planet.
But until recent studies, the conventional wisdom was that ice cover prevented the growth of phytoplankton for most of the year in the ocean around Antarctica because very little sunlight could penetrate to the water below. However, new evidence shows there are just enough cracks, thin spots, and gaps to let sufficient daylight through the sea ice.
“Around Antarctica, the compact sea ice seems pretty impenetrable to light,” said Chris Horvat, a sea ice scientist at Brown University and the lead author of the new study. In the wide and coarse views from most satellites, ice cover can appear uniform and sheet-like, reinforcing the idea that light would be too scarce and faint for plant-like life below.
But viewed from below the ocean surface—and now with the laser eyes of NASA’s Ice, Cloud and land Elevation Satellite 2 (ICESat-2)—scientists see that Antarctic sea ice is actually riddled with fractures and openings. Sunlight slips through the cracks and provides the energy for notable under-ice blooms in the Southern Ocean. For reference, the photograph below shows an aerial view of sea ice around Antarctica on October 29, 2017.
Horvat and colleagues pulled together three lines of evidence. First, they examined data collected by with the laser eyes of NASA’s Argo floats—underwater instruments that measure different properties of the ocean from the surface to roughly 2,000 meters (7,000 feet) in depth. The cylinder-shaped instruments drift with currents and rise and fall through the ocean, occasionally surfacing to relay their data back to land-based laboratories via satellite transmitters. Argo floats deployed since 2014 can detect the presence of chlorophyll and particulate carbon in the water, both of which can indicate the presence of phytoplankton.
Examining data from more than 2,000 under-ice dives over seven years, the research team found that nearly all measurements showed phytoplankton accumulating even before the sea ice had retreated in Southern Hemisphere spring and summer. In a quarter of those measurements, enough phytoplankton had amassed to suggest blooming events were underway.
Given those observations, the team analyzed ice conditions with ICESat-2 data to develop a picture of where and how much light was penetrating through the cracks and openings in Antarctic sea ice. The primary instrument on ICESat-2 is a laser altimeter, which sends pulses of light toward Earth’s surface and then measures, to within a billionth of a second, how long it takes individual photons to return to the satellite. From this information scientists can derive the height of sections of ice—and also spot the cracks and gaps between them.
Finally, building off of ice-cover models from the Coupled Model Intercomparison Project Phase 6, Horvat and colleagues estimated the location and thickness of Southern Ocean ice cover and how it moved. They also derived estimates of photosynthetically available radiation (PAR), a measure of the sunlight needed to sustain blooms in the ocean. They found 3 to 5 million square kilometers (1.2 to 1.9 million square miles)—an area larger than India—of the ice-covered Southern Ocean could allow enough light to penetrate and support some under-ice blooms.
Data collected during the study are represented on the maps at the top of this page. The left map shows the location and abundance of likely phytoplankton blooms and their position within the icepack from 2014-2020. The right map combines satellite data and models to show where there was likely enough light penetrating the ice to sustain blooms.
“Scientists have talked about the potential for blooms here, but this is the first time we are seeing them under the ice in Antarctic waters,” said Horvat. “The blooms have probably always been there, we just haven’t had the capacity to observe them. This finding opens up a whole new way of thinking about life around and under the ice. Sea ice is more interesting and diverse than people think, and it can support a wide range of ecological communities.”
Horvat is part of a team that is developing new sea ice products from ICESat-2 to get an even better sense of the mosaic-like texture of sea ice. They also hope to follow up on the under-ice bloom study by investigating how extensive and how frequent the blooms are, and if there is seasonality to them.
“The paper describes some interesting observations in a relatively poorly studied region of the global ocean,” added Michael Behrenfeld, an Oregon State University ocean ecologist who was not part of the study. “Under-ice blooms have earlier been reported in the Arctic, but this new study clearly documents these types of blooms in the Southern Ocean. An important difference between these two polar regions is that the total area of suitable conditions for under-ice blooms is much greater around Antarctica. Thus, when integrated over area, these Southern Ocean blooms may be a very large mass of plankton.”
NASA Earth Observatory image by Joshua Stevens, using data courtesy of Horvat, C., et al. (2022). Photo by NASA/Nathan Kurtz. Story by Michael Carlowicz/NASA’s Earth Science Division.
FAQs
Most phytoplankton productivity occurs before the sea ice has broken up, and thus was not observable until recently. This discovery suggests that nutrients like iron are supplied by melting ice, feeding phytoplankton communities and having a potential impact on broader ecology in the Southern Ocean.
Are there phytoplankton in Antarctica? ›
A decade ago, scientists on a NASA-sponsored ocean expedition found massive populations of phytoplankton blooming beneath sea ice in the Arctic Ocean. Now scientists using underwater instruments and a NASA satellite have found evidence of potentially significant blooms beneath the sea ice encircling Antarctica.
What type of plankton blooms under Arctic sea ice? ›
Now there is a growing body of evidence that suggests under-ice blooms (UIBs) of phytoplankton, like a sudden spring flowering in a garden, can occur in low-light environments below sea ice.
What is a possible cause of change in the phytoplankton in the Antarctic? ›
Changes such as increased wind-driven mixing re sulting in re- duced stratification early in the season can shift the timing of the start date of the phytoplankton accumu- lation season later in the year, a scenario which has been observed in other polar seas with seasonal sea ice (Stabeno et al.
In what part of the ocean are phytoplankton found? ›
Phytoplankton, also known as microalgae, are similar to terrestrial plants in that they contain chlorophyll and require sunlight in order to live and grow. Most phytoplankton are buoyant and float in the upper part of the ocean, where sunlight penetrates the water.
Is there an ecosystem under Antarctica? ›
The secret ecosystem was found more than 1,600 feet below the surface. A never-before-seen ecosystem lurks in an underground river deep below the icy surface in Antarctica.
What lives underwater in Antarctica? ›
At least 235 marine species are found in both Antarctica and the Arctic, ranging in size from whales and birds to small marine snails, sea cucumbers, and mud-dwelling worms. The large animals often migrate between the two, and smaller animals are expected to be able to spread via underwater currents.
What did NASA find in Antarctica? ›
NASA. View larger image. Researchers at the University of Texas at Austin, NASA and other research organizations have discovered two seafloor troughs that could allow warm ocean water to reach the base of Totten Glacier, East Antarctica's largest and most rapidly thinning glacier.
How does sea ice affect phytoplankton? ›
Most phytoplankton productivity occurs before the sea ice has broken up, and thus was not observable until recently. This discovery suggests that nutrients like iron are supplied by melting ice, feeding phytoplankton communities and having a potential impact on broader ecology in the Southern Ocean.
Can plankton survive in ice? ›
In the Arctic, these algae can live in sea ice (ice algae) and in the water column (phytoplankton). Scientists use satellite-based observations of chlorophyll (the green pigment vital for photosynthesis) as a proxy for phytoplankton productivity.
Baleen whales, seals, and penguins eat krill, their breeding success depends on it, and krill depend on sea ice and phytoplankton to survive. All the breeding cycles of Antarctic animals – from big to small — occur in synchrony and follow in succession with the spring phytoplankton blooms that come after winter's end.
Is climate change killing phytoplankton? ›
Some plankton, such as diatoms, grow better at cooler temperatures. Warming may cause other, less palatable, species to replace them, depriving zooplankton and menhaden of their primary food source. Because phytoplankton are linked to freshwater and nutrient inputs, draught will likely decrease their abundance.
What causes an increase in phytoplankton? ›
Phytoplankton growth depends on the availability of carbon dioxide, sunlight, and nutrients. Phytoplankton, like land plants, require nutrients such as nitrate, phosphate, silicate, and calcium at various levels depending on the species.
What eats phytoplankton? ›
Phytoplankton and algae form the bases of aquatic food webs. They are eaten by primary consumers like zooplankton, small fish, and crustaceans. Primary consumers are in turn eaten by fish, small sharks, corals, and baleen whales.
What is phytoplankton good for? ›
Phytoplankton are microscopic plants floating around in marine and aquatic ecosystems that produce 50-80% of the world's oxygen. Besides providing food for countless other organisms, they are so effective at absorbing carbon dioxide that some have suggested growing phytoplankton as a solution to climate change.
Why are phytoplankton important to humans? ›
Plankton are at the base of the food chain, meaning they are critical in supporting marine and freshwater food webs. Phytoplankton are also primary produces, meaning they use photosynthesis to convert carbon dioxide to oxygen, and are responsible for up to half of the oxygen we breathe.
Does phytoplankton live in Arctic? ›
In the Arctic, these algae can live in sea ice (ice algae) and in the water column (phytoplankton). Scientists use satellite-based observations of chlorophyll (the green pigment vital for photosynthesis) as a proxy for phytoplankton productivity.
Where is phytoplankton found in the world? ›
Phytoplankton thrive along coastlines and continental shelves, along the equator in the Pacific and Atlantic Oceans, and in high-latitude areas. Winds play a strong role in the distribution of phytoplankton because they drive currents that cause deep water, loaded with nutrients, to be pulled up to the surface.
Who eats phytoplankton in the Arctic? ›
Phytoplankton and ice algae are eaten by zooplankton, and in turn, zooplankton are eaten by polar cod, seabirds, and the bowhead whales. This shows how both phytoplankton and zooplankton are an incredibly important food supply to the rest of the Arctic's ecosystem.
Are there underwater plants in Antarctica? ›
Algae are an extremely diverse group of aquatic plants, and are found in the waters, ice and land throughout Antarctica. Snow algae grow in semi-permanent to permanent snow or ice in the alpine or polar regions of the world. Their optimum…
