Each summer, the Southern Ocean surrounding Antarctica turns a brighter shade of green. Vast blooms of phytoplankton spreading across the water, forming the base of one of the most important marine food webs on the planet. These blooms also play a role in drawing carbon dioxide out of the atmosphere. For years, scientists have explained seasonal growth through sunlight, wind patterns and ocean circulation. New research now points to another influence, less obvious and far deeper. Earthquakes occurring beneath the seafloor may be shaping how much life appears at the surface months later.
Earthquakes under the ocean floor may be feeding Antarctic life
Research with the title “Southern Ocean net primary production influenced by seismically modulated hydrothermal iron” analysed satellite data alongside seismic records from the Southern Ocean. They focused on earthquakes with a magnitude of five or greater that occurred in the months before the peak summer growing season. The pattern they found was consistent. Years with higher seismic activity were followed by denser and more extensive phytoplankton blooms. In quieter seismic years, the blooms were noticeably smaller.The size of these blooms varied dramatically. In some summers, the green patch covered an area comparable to a large US state. In others, it shrank to a fraction of that size. The strongest link between these swings was not weather or sunlight, but the level of earthquake activity beneath the ocean floor.
Hydrothermal vents act as hidden nutrient sources
The connection lies in hydrothermal vents. These are natural openings in the seabed where seawater circulates through hot rock deep within Earth’s crust. As the water heats up, it dissolves minerals and metals, including iron, before flowing back into the ocean. Iron is scarce in much of the Southern Ocean, yet it is essential for phytoplankton growth.Under normal conditions, much of this iron stays deep. It mixes slowly and often never reaches the surface in meaningful amounts. Earthquakes appear to change that balance. When the crust shifts, hydrothermal systems can briefly intensify. These jolts release pulses of iron rich fluid into surrounding waters.
Nutrients move upward faster than expected
One of the more surprising findings from the study was how quickly these nutrients seem to reach the surface. Conventional thinking suggested that iron released at depth would take decades to rise thousands of feet. The new analysis suggests it can happen in weeks or a few months.The process is uneven and sudden. Rather than a steady flow, it resembles a disturbance that stirs long settled layers. Once iron enters upper waters, phytoplankton respond quickly. Growth accelerates, and blooms expand across large areas.
Southern Ocean ecosystems respond strongly to iron
The Southern Ocean is known as a high nutrient low chlorophyll region. Other nutrients and sunlight are often available, yet phytoplankton growth remains limited by iron. When that constraint is lifted, even briefly, the ecosystem reacts.Larger blooms support more zooplankton, which in turn feed fish and higher predators. The effects ripple upward through the food web. At the same time, increased phytoplankton activity strengthens the ocean’s ability to absorb carbon dioxide through photosynthesis.
Carbon uptake may rise during active years
As phytoplankton grow, they take in carbon dioxide from the air and surface waters. Some of that carbon eventually sinks to deeper layers when organisms die or are consumed. This process forms part of the biological carbon pump, a key mechanism in regulating Earth’s climate.How much earthquake driven nutrient input contributes to global carbon cycling remains uncertain. The Southern Ocean covers a vast area, and even small changes there can have outsized effects. Researchers caution that this mechanism is episodic, not constant, but its impact during active periods may be significant.
A factor missing from many climate models
Most climate and ocean models focus on continuous forces such as winds, currents and seasonal mixing. Earthquakes do not fit easily into those frameworks. They are unpredictable, brief and unevenly distributed. Yet this study suggests they can produce large biological responses.Other parts of the world also host hydrothermal systems. Whether similar effects occur elsewhere is still unclear, largely because deep ocean regions are difficult to monitor. Improved sensors and longer satellite records may help fill those gaps. For now, the findings add another layer to how scientists understand the ocean. Beneath the calm surface patterns tracked each year, deeper processes are at work. Some of them arrive without warning, leave subtle traces, and quietly shape life far above the seafloor.