.国产短视频

国产短视频

国产短视频College of Marine Science

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Study identifies nutrients as driver of the Great Atlantic Sargassum Belt

The Great Atlantic Sargassum Belt stretches 5,000 miles from West Africa to the Gulf of Mexico. Courtesy of Ellen Park.

The Great Atlantic Sargassum Belt stretches 5,000 miles from West Africa to the Gulf of Mexico. .

This article was adapted from .

Under normal conditions, the floating macroalgae Sargassum spp. provide habitat for hundreds of types of organisms. However, the Great Atlantic Sargassum Belt (GASB) that emerged in 2011 has since then caused unprecedented inundations of this brown seaweed on Caribbean and Florida coastlines, with harmful effects on ecosystems while posing concerns for regional economies and public health.

In published in Nature Communications, researchers say they have identified that the nutrient content of Sargassum tissue could help determine the enrichment sources and potentially improve predictions and Sargassum management efforts.

鈥淭his study shows nutrient enrichment in Sargassum in the western portion of the Great Atlantic Sargassum Belt as compared with Sargassum in the Sargasso Sea,鈥 said Chuanmin Hu, professor and director of the at the 国产短视频 College of Marine Science, and one of the study鈥檚 co-authors. 鈥淭he findings point to the need for more measurements to pinpoint the nutrient sources. This is a critical step toward the understanding of the increased Sargassum inundations in recent years.鈥

Hu鈥檚 satellite-based Sargassum maps provided the context of the Sargassum samples as well as their oceanic environments.

The Great Atlantic Sargassum Belt seen from satellite. Image courtesy of Chuanmin Hu and Brian Barnes.

The Great Atlantic Sargassum Belt seen from satellite. Image courtesy of Chuanmin Hu and Brian Barnes.

A variety of nutrient sources for the GASB blooms have been suggested, including upwelling, vertical mixing, discharge from the Amazon and Congo rivers, and atmospheric deposition. However, the paper states that the causes of the GASB and the mechanisms controlling its variability remain unknown.

The paper also indicates that the nutritional status of Sargassum in the GASB is enriched, with higher nitrogen and phosphorus content than the populations of Sargassum that reside in its Sargasso Sea habitat.

鈥淚n its traditional environment, Sargassum is a great ecological benefit,鈥 said Dennis McGillicuddy, Jr., senior scientist in the at the Woods Hole Oceanographic Institution (WHOI) and the article鈥檚 lead author. 鈥淗owever, the proliferation of biomass in the tropical Atlantic has proven the old adage that too much of a good thing can be bad.鈥

The finding that nitrogen and phosphorus are higher in the GASB than in the Sargasso Sea 鈥渋s a smoking gun that the GASB inundations are nutrient-driven,鈥 said McGillicuddy. 鈥淎 consequence of this finding is that it presents us potentially with the opportunity to use those nitrogen and phosphorus markers in Sargassum tissue to fingerprint the ultimate sources of these nutrients that are sustaining these seaweed blooms.鈥

In addition, the paper notes that the presence of arsenic in Sargassum tissue 鈥 which reflects phosphorus limitation 鈥 significantly constrains the utilization of the seaweed biomass that washes ashore.

鈥淎s the Great Atlantic Sargassum Belt has grown over the last decade, the public has become increasingly aware of this phenomenon and its impact on coastal communities,鈥 said Peter Morton, research scientist in the , College Station and a co-author of the study. 鈥淥ur research shows that Sargassum could become enriched in arsenic, depending on the conditions in which it grows. Plans to remove or exploit this material when it washes ashore should consider the potential for Sargassum to contain high concentrations of arsenic, so we encourage affected communities to proceed with caution when exploring options to deal with seasonal inundations of Sargassum.鈥

Due to the threats that the Sargassum inundations pose to the environment, economy, and human health, the paper recommends the need for expanded observational and modeling studies to understand the GASB鈥檚 physical, biological, and chemical drivers.

McGillicuddy and co-author Brian Lapointe also stressed the importance of the interdisciplinary and collaborative nature of this research, which encompasses several disciplines including biology, chemistry, and physics.

鈥淭his collaborative study illustrates the value of interdisciplinary research teams to understanding complex oceanographic phenomena in an era of rapid global change, in this case, the Great Atlantic Sargassum Belt that formed in 2011,鈥 said Lapointe, a research professor at , and one of the world鈥檚 foremost authorities on Sargassum.

Funding for this research was provided by the , the through the , , the Isham Family Charitable Fund, , and .

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