Mangroves
Mangroves are unique tropical and subtropical trees belonging to the genus Rhizophora and the family Rhizophoraceae. Commonly found in shallow, protected coastal waters such as intertidal zones, bays, and estuaries, these trees thrive in saline environments and can tolerate high salinity levels. Mangrove forests, which may also be referred to as mangrove swamps or mangals, play a crucial role in coastal ecosystems, offering habitat for various marine species, including juvenile fish. Despite covering only about 0.1 percent of the Earth’s surface, mangroves are vital for carbon storage, sequestering up to ten times more carbon per hectare than terrestrial forests.
However, human activities, such as urban development and shrimp aquaculture, have led to significant declines in mangrove areas, exacerbating challenges posed by climate change, including rising sea levels and increased salinity. Restoration projects, like the Manzanar Mangrove Initiative and Vida Manglar in Colombia, aim to replenish and protect mangrove ecosystems, recognizing their importance in combating climate change and providing coastal protection. These initiatives highlight the delicate balance needed to preserve mangroves while addressing ecological and community needs.
Subject Terms
Mangroves
Definition
Mangroves are both a genus of tropical and subtropical trees, the Rhizophora, and the family of plants to which the genus belongs, the Rhizophoracae. The term most commonly refers to an assemblage of mangrove trees and other associated trees and shrubs that includes more than one hundred species. Such an assemblage may also be called a mangrove swamp, a mangrove forest, or a mangal.
Mangroves occur in shallow, protected coastal waters, such as flats in intertidal zones, bays, and estuaries in the tropics and subtropics. They cannot survive freezing or even consistently cold water. They are usually canopied forests up to about 10 meters tall, although in rare cases, old-growth mangroves can reach 40 meters in height.
Mangroves survive in a difficult niche. They must be salt-tolerant plants ( halophytes), and some can thrive in water of twice the salinity of seawater. Mangrove roots can filter salt from water intake, and those growing in the most saline areas excrete salt from their leaves. Mangrove forests shade from the most salt-tolerant species on their seaward side to the least salt-tolerant species on their landward side, and they shade to conventional forests or freshwater plants.
Mangrove mudflats tend to be oxygen poor (hypoxic), to contain toxic levels of sulfides, to be subject to periodic flooding, and to be very weak for holding trees. Consequently, mangroves have a maze of roots, some of which (pneumataphores) reach up out of the water to get oxygen, while some function as stilts to help brace the trees.
The mangrove niche between freshwater, dry land, and the ocean is very small, perhaps only 0.1 percent of the Earth’s surface. However, it is very important for three reasons: The maze of roots catches nutrient flows from the land and holds them for gradual release to the sea rather than short, polluting surges. Conversely, the roots protect the land from ordinary erosion and disasters such as hurricanes and tsunamis. Finally, the maze of roots holding leaves and nutrients from shore provides habitat and food for sea life. Young fish from as many as three-quarters of tropical deepwater fish species live in mangroves.
Significance for Climate Change
Mangrove forests may cover only 0.1 percent of the planet’s surface, but they store up to ten times more carbon per hectare than terrestrial forests. This carbon-storing superpower makes mangroves an integral part of the solution to climate change. Theoretically, mangroves would benefit from global warming, because their tropical climate area would extend farther toward the poles. More mangroves would increase the capture (sequestration) of carbon from atmospheric and help reduce the greenhouse effect. Moreover, increased mangrove buffering of nutrient surges washing off the land would release a steadier, gentler flow of dissolved organic compounds, allowing plankton and other marine plants to capture more CO2 from the air and increase the oceans’ reflectivity. Thus, mangroves would create a significant negative feedback retarding global warming.
In practice, however, the decline of mangroves due to human development may be a significant positive driver of global warming. The percentage of Earth’s surface covered by mangroves has been cut in half (from 0.2 percent to 0.1 percent) in the last century, mostly as a result of human development. For instance, sand dredged from Biscayne Bay, Florida, buried a mangrove swamp, and built a city—Miami. Increases in shrimp aquaculture have also caused major destruction of mangroves.
A 2024 study by the International Union for Conservation of Nature found that half the world's mangroves are in danger of collapsing from sea level rise caused by climate change. Salinity is toxic to mangrove trees, but they can tolerate a small amount. However, rising water levels have inundated them with salinity, killing many of them. So much salinity also makes it harder for them to germinate and produce new trees. Scientists believe the only way to remedy the situation long-term is for the world to reduce or eliminate the burning of fossil fuels, eventually relying solely on renewable energy sources.
It was theorized that such rising sea levels could also cause mangroves to retreat from the deeper water and attempt to colonize new inland swampy areas. However, people would likely erect dikes to protect existing structures and agricultural land. Hence, the effective surface area available for mangroves would be constricted even further. This reduction in surface area would decrease the area of ocean fertility, the corresponding amount of carbon sequestration, and the buffering of the land against ocean disasters. Indeed, the damage to New Orleans caused by Hurricane Katrina in 2005 can be partly attributed to reduced swamplands around the city, which left the dikes more vulnerable (although the major causes of losses in New Orleans were and navigation channels). In 2020, flooding in Mumbai, India, was also blamed on mangrove destruction.
A number of groups have tried to replenish mangroves and even establish them in new areas. The best-known of these is the Manzanar Mangrove Initiative, which is backed by the Eritrean government on the East African coast. (It was largely sparked by Gordon Sato, who was interned during World War II at Manzanar, California.) The Manzanar Mangrove Initiative uses small amounts of fertilizer in bags for slow release to vastly increase the area of mangroves and resulting silage for livestock.
An extension of the Manzanar Mangrove Initiative would pump seawater into desert areas to vastly increase mangrove areas, food production, and capture of CO2 from the atmosphere. However, the required pumping would require major investments in either some form of alternate energy or fossil-fuel-fired power for the pumping. Moreover, skeptics of the Manzanar Mangrove Initiative worry that overzealous fertilization of the mangroves might damage coral reefs further out to sea. An additional mangrove project in Cispata, Colombia, partially funded by Apple and known locally as Vida Manglar, allowed a local mangrove forest to become the first to enter the carbon market in 2021.
Bibliography
Hogarth, Peter J. The Biology of Mangroves and Seagrasses. 2d ed. New York: Oxford University Press, 2007.
Lieth, Helmut, Maximo Garcia Sucre, and Brigitte Herzog, eds. Mangroves and Halophytes: Restoration and Utilisation. New York: Springer, 2008.
"Mangroves Destruction to Blame for Flooding in Mumbai: Experts" The New Indian Express, 6 Aug. 2020, www.newindianexpress.com/cities/mumbai/2020/aug/06/mangroves-destruction-to-blame-for-flooding-in-mumbai-experts-2179916.html. Accessed 11 Jan. 2023.
Onorevole, Kathleen. "The Manzanar Project and the World's Most Unlikely Mangroves." Under the C, 29 Oct. 2015, underthecblog.org/2015/10/29/the-manzanar-project-and-the-worlds-most-unlikely-mangroves/. Accessed 11 Jan. 2023.
Saenger, P. Mangrove Ecology, Silviculture, and Conservation. New York: Springer, 2003.
Sato, Gordon, et al. “A Novel Approach to Growing Mangroves on the Coastal Mud Flats of Eritrea with the Potential for Relieving Regional Poverty and Hunger.” Wetlands 25, no. 3 (September, 2005): 776-779.
"Share the Facts about Mangroves." Conservation International, www.conservation.org/act/share-the-facts-about-mangroves. Accessed 13 Dec. 2024.
Simon, Julia. "Mangroves Protect Communities from Storms. Half Are at Risk of Collapse, Study Says." NPR, 22 May 2024, www.npr.org/2024/05/22/1252846086/climate-change-mangrove-sea-level-collapse-red-list. Accessed 10 Dec. 2024.