Red Sea mangroves explained

The Red Sea mangroves ecoregion is defined by One Earth to span mangrove forests along the coast of the Red Sea.^[1] The ecoregion has no source of fresh water and the temperatures get high in the summer (e.g., over 31C) which causes the salinity of the mangrove forest to be high.^[1] The soils of the ecoregion are carbonates, which are poor in iron. The unusual soil stunts the growth of the mangroves, limiting their height to approximately 20NaN0.^[2]

The dominant mangrove species is Avicennia marina, with Rhizophora mucronata, Bruguiera gymnorhiza, and Ceriops tagal in a few areas.^[3] Avicennia marina occurs in pure stands, excluding other mangrove species.^[3] The mangroves cover 175km2 of area.^[4] Despite a global decline in mangrove ecosystems, the area of Red Sea mangroves has grown from 1972 to 2013.^[5]

The ecoregion serves as an important habitat for migratory birds, such as cormorants, egrets, herons, kingfishers, ospreys, pelicans, and waders. Birds native to the ecoregion include black kites, Goliath herons, pink-backed pelicans, and western reef herons. The mangroves serve as important nursery habitat for sea life, which includes black seabream, common ponyfish, jellyfish, milkfish, sea spiders, and tiger perch.^[1]

More than 76 species of marine macroalgae are associated with the mangroves. Species such as Sargassum dentifolium and Turbinaria triquetra grow in thick mats and contribute a substantial amount of the nitrogen and biomass of the mangrove forest.^[6] Thirty-nine species of marine fungus grow on the decaying wood of the mangroves, with Swampomyces armeniacus being the most common.^[7]

In addition to contributing to biodiversity, the Red Sea mangroves provide other ecosystem services: they protect the coast from erosion and storms,^[8] absorb pollution, and supply breeding ground for commercial fisheries.^[1] Mangroves also sequester a large amount of carbon from the atmosphere.^[9]

Notes and References

1. Web site: Red Sea Mangroves. One Earth. Emma. Martin. Neil. Burgess. 27 May 2024.
2. Almahasheer. H. Duarte. CM. Irigoien. X. Nutrient Limitation in Central Red Sea Mangroves. Frontiers in Marine Science. 3. 2016. 10.3389/fmars.2016.00271. free.
3. Book: Khalil, ASM. 2015. Mangroves of the Red Sea. Rasul. N. Stewart. I. The Red Sea. Springer Earth System Sciences. 585–597 . Springer. Berlin. 10.1007/978-3-662-45201-1_33. 978-3-662-45200-4 .
4. J. Blanco-Sacristán. K. Johansen. CM. Duarte. D. Daffonchio. I. Hoteit. MF. McCabe. Mangrove distribution and afforestation potential in the Red Sea. Science of the Total Environment. 843. 2022. 157098. 10.1016/j.scitotenv.2022.157098. 35779736 . 2022ScTEn.84357098B .
5. H. Almahasheer. A. Aljowair. CM. Duarte. X. Irigoien. Decadal stability of Red Sea mangroves. Estuarine, Coastal and Shelf Science. 169. 2016. 164–172. 10.1016/j.ecss.2015.11.027. 2016ECSS..169..164A . 10754/584005 . free.
6. Mangrove ecosystem of Saudi Arabian Red Sea Coast — an overview. SM. Saifullah. Journal of King Abdulaziz University: Marine Sciences. 7. 263–270. 1996. 10.4197/mar.7-1.23 .
7. Abdel-Wahab. MA. Diversity of marine fungi from Egyptian Red Sea mangroves. Botanica Marina. 48. 5. 2005. 348–355. 10.1515/BOT.2005.047.
8. Das. S. JR. Vincent. Mangroves protected villages and reduced death toll during Indian super cyclone. Proceedings of the National Academy of Sciences. 106. 18. 2009. 7357–7360. 10.1073/pnas.0810440106. free. 19380735. 2678660. 2009PNAS..106.7357D.
9. Donato. DC. Kauffman. JB. Murdiyarso. D. Kurnianto. S. Stidham. M. Kanninen. M. 2011. Mangroves among the most carbon-rich forests in the tropics. Nature Geoscience. 4. 5. 293–297. 10.1038/ngeo1123 . 2011NatGe...4..293D .