Record Sargassum Bloom Sends Seaweed Drifting Towards Florida
An unwelcome visitor is headed for Florida and the Caribbean: huge floating mats of sargassum, or free-floating brown seaweed. Nearly every year since 2011, sargassum has inundated Caribbean, Gulf of Mexico and Florida coastlines in warm months, peaking in June and July. This brown tide rots on the beach, driving away tourists, harming local fishing industries and requiring costly cleanups.
According to scientists who monitor the formation of sargassum in the Atlantic Ocean, 2023 could produce the largest bloom ever recorded. That’s bad news for destinations like Miami and Fort Lauderdale that will struggle to clean their shorelines. In 2022, Miami-Dade County spent US$6 million to clear sargassum from just four popular beaches.
Satellite image of sargassum concentrations in the Atlantic during the month of March. USF/NOAA, CC BY-ND
Sargassum isn’t new on South Florida beaches, but its rapid increase over the past decade indicates that some new factor – likely related to human actions – is affecting when and how it forms.
In my work as a coastal scientist, I’ve watched these invasions become the new normal, choking beaches and turning clear blue waters golden brown. Along with other researchers, I’m trying to understand why sargassum has proliferated into this new sprawling bloom, how to deal with such massive amounts of it, and how affected countries can predict the severity of the next influx.
A biological hot spot at sea
Sargassum grows in the calm, clear waters of the Sargasso Sea – a 2 million-square-nautical-mile (5.2 million-square-kilometer) haven of biodiversity that lies east of Bermuda in the Atlantic Ocean. Rather than beaches, it’s bounded by rotating ocean currents that form the North Atlantic Subtropical Gyre.
The Sargasso Sea in the North Atlantic is bounded by the Gulf Stream to the west, the North Atlantic Current to the north, the Canary Current to the east, and the North Equatorial Current to the south. Jack/Wikipedia
In the open ocean, islands of sargassum create a rich ecosystem that ocean explorer Sylvia Earle calls “a golden floating rainforest.” Suspended by round “berries” filled with gas, the seaweed offers food, sanctuary and breeding grounds for crabs, shrimp, whales, migratory birds and some 120 species of fish. Mats of it form the sole spawning grounds for European and American eels and habitat for some 43 other threatened or endangered species.
Sargassum also shelters sea turtle hatchlings and juvenile fish during their early life in the open ocean. Ten endemic species live nowhere else on Earth. The Sargasso is a valuable commercial fishery worth about $100 million per year.
But in recent years, large quantities of sargassum have drifted west, forming what researchers call the Great Atlantic Sargassum Belt. As of late March 2023, the sargassum belt was about 5,000 miles (8,000 kilometers) long and 300 miles (500 miles) wide
The belt is actually a collection of island-like masses that can stretch for miles. It doesn’t uniformly cover beaches when it washes up: Some areas can be relatively clear or only mildly affected. But the overall mass this year is overwhelming.
What’s fertilizing huge blooms?
What can plausibly explain the sudden increase in this floating seaweed since 2011 – the first time that large aggregations of sargassum were detected from space? While climate change is warming ocean waters, and sargassum grows faster in warmer water, I believe it’s more plausible that the cause is a drastic increase in agricultural activity in the Brazilian Amazon.
Scientists have shown that huge brown tides that were observed in the Gulf of Mexico in 2005 and 2011 were linked to nutrients carried down the Mississippi River. Now, intensive cattle ranching and soybean farming in the Amazon basin are sending rising levels of nitrogen and phosphorus into the Atlantic Ocean via the Amazon and Orinoco rivers. These nutrients are key ingredients in fertilizer, and also are present in animal manure.
Another major source of nutrients is dust clouds from the Sahara, which can stretch for thousands of miles across the Atlantic Ocean, carried by trade winds. These clouds contain iron, nitrogen and phosphorus from dust storms in Saharan Africa and biomass burning in central and southern Africa. As they blow across the Atlantic, they help fertilize seaweed.
This map shows dust from a series of Saharan storms crossing the Atlantic on June 28, 2018. NASA Earth Observatory
A threat to sea life
Along with its devastating effects on recreational beaches in the Caribbean and South Florida, sargassum has important but less visible ecological impacts near the coast. Large floating mats of sargassum block sunlight, which is essential for the survival of underwater grasses. These grasses stabilize the seafloor and provide food and shelter for many species of fish and invertebrates and for Florida’s endangered manatees.
Coral reefs also require sunlight and clean water to survive. Reefs in Florida and the Caribbean are under many other stresses, including ocean warming and coral bleaching, so they are already highly vulnerable.
Thick masses of sargassum on beaches can make it difficult or impossible for endangered sea turtles to dig nests and lay eggs on beaches. Spring and summer, when sargassum accumulates, are prime sea turtle nesting seasons.
Taming the sargassum monster
Researchers across the Caribbean are working to find productive uses for these enormous quantities of organic material that float ashore. In South Florida, communities mainly use the seaweed as mulch, but this requires thoroughly washing it to remove the salt, either naturally via rainfall or by spraying it with fresh water. Recycling sargassum into fertilizer for use on crops is problematic because it often contains toxic heavy metals such as arsenic and cadmium.
Sargassum has become a recurring seaweed monster, but humanity is the real villain. Until nations find ways to reduce large-scale nutrient pollution, I expect that huge sargassum blooms will be a recurring presence in Florida and the Caribbean.
Stephen P. Leatherman is a Professor of Coastal Science at Florida International University.
This article appears courtesy of The Conversation and may be found in its original form here.
The opinions expressed herein are the author's and not necessarily those of The Maritime Executive.