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'''Seaweed''', or '''macroalgae''', refers to thousands of species of [[Macroscopic scale|macroscopic]], [[Multicellular organism|multicellular]], [[ocean|marine]] [[algae]]. The term includes some types of ''[[Rhodophyta]]'' (red), ''[[Phaeophyta]]'' (brown) and ''[[Chlorophyta]]'' (green) macroalgae. Seaweed species such as [[kelp]]s provide essential nursery habitat for fisheries and other marine species and thus protect food sources; other species, such as [[plankton]]ic algae, play a vital role in [[Blue carbon|capturing carbon]], producing up to 90% of Earth's oxygen.
'''Seaweed''', or '''macroalgae''', refers to thousands of species of [[Macroscopic scale|macroscopic]], [[Multicellular organism|multicellular]], [[ocean|marine]] [[algae]]. The term includes some types of ''[[Rhodophyta]]'' (red), ''[[Phaeophyta]]'' (brown) and ''[[Chlorophyta]]'' (green) macroalgae. Seaweed species such as [[kelp]]s provide essential nursery habitat for fisheries and other marine species and thus protect food sources; other species, such as [[plankton]]ic algae, play a vital role in [[Blue carbon|capturing carbon]], producing up to 90% of Earth's oxygen.


Natural seaweed ecosystems are sometimes under threat from human activity. For example, mechanical dredging of kelp destroys the resource and dependent fisheries. Other forces also threaten some seaweed ecosystems, for example a wasting disease in predators of [[purple urchin]]s has led to a urchin population surge which destroyed large [[kelp forest]] regions off the coast of California.<ref>{{Cite web|title=California's crashing kelp forest|url=https://phys.org/news/2019-10-california-kelp-forest.html|access-date=2021-02-24|website=phys.org|language=en}}</ref>
Natural seaweed ecosystems are sometimes under threat from human activity. For example, mechanical dredging of kelp destroys the resource and dependent fisheries. Other forces also threaten some seaweed ecosystems; a wasting disease in predators of [[purple urchin]]s has led to a urchin population surge which destroyed large [[kelp forest]] regions off the coast of California.<ref>{{Cite web|title=California's crashing kelp forest|url=https://phys.org/news/2019-10-california-kelp-forest.html|access-date=2021-02-24|website=phys.org|language=en}}</ref>


Humans have a long history of cultivating seaweeds for their use. In recent years, [[seaweed farming]] has become a global agricultural practice, providing food, source material for various chemical uses (such as [[Carrageenan]]), cattle feeds and fertilizers. Because of their importance in marine ecologies and for absorbing carbon dioxide, recent attention has been on cultivating seaweeds as a potential [[climate change mitigation]] strategy for [[Biosequestration|biosequestration of carbon dioxide]], alongside other benefits like [[nutrient pollution]] reduction, increased habitat for coastal aquatic species, and reducing local [[ocean acidification]].<ref name=":12">{{Cite journal|last1=Duarte|first1=Carlos M.|last2=Wu|first2=Jiaping|last3=Xiao|first3=Xi|last4=Bruhn|first4=Annette|last5=Krause-Jensen|first5=Dorte|date=2017|title=Can Seaweed Farming Play a Role in Climate Change Mitigation and Adaptation?|journal=Frontiers in Marine Science|language=en|volume=4|doi=10.3389/fmars.2017.00100|issn=2296-7745|doi-access=free}}</ref> The IPCC [[Special Report on the Ocean and Cryosphere in a Changing Climate]] recommends "further research attention" as a mitigation tactic.<ref name=":2">{{Cite book|last1=Bindoff|first1=N. L.|title={{Harvnb|IPCC SROCC|2019}}|last2=Cheung|first2=W. W. L.|last3=Kairo|first3=J. G.|last4=Arístegui|first4=J.|last5=Guinder|first5=V. A.|last6=Hallberg|first6=R.|last7=Hilmi|first7=N. J. M.|last8=Jiao|first8=N.|last9=Karim|first9=Md S.|year=2019|pages=447–587|chapter=Chapter 5: Changing Ocean, Marine Ecosystems, and Dependent Communities|ref={{harvid|IPCC SROCC Ch5|2019}} <!-- ipcc:20200202 -->|display-authors=4|chapter-url=https://www.ipcc.ch/site/assets/uploads/sites/3/2019/11/09_SROCC_Ch05_FINAL.pdf|first10=L.|last16=Williamson|first16=P.|last15=Tagliabue|first15=A.|last14=Suga|last12=Purca Cuicapusa|last13=Rinkevich|first13=B.|first12=S. R.|last11=O'Donoghue|first11=S.|last10=Levin|first14=T.}}</ref>
Humans have a long history of cultivating seaweeds for their use. In recent years, [[seaweed farming]] has become a global agricultural practice, providing food, source material for various chemical uses (such as [[Carrageenan]]), cattle feeds and fertilizers. Because of their importance in marine ecologies and for absorbing carbon dioxide, recent attention has been on cultivating seaweeds as a potential [[climate change mitigation]] strategy for [[Biosequestration|biosequestration of carbon dioxide]], alongside other benefits like [[nutrient pollution]] reduction, increased habitat for coastal aquatic species, and reducing local [[ocean acidification]].<ref name=":12">{{Cite journal|last1=Duarte|first1=Carlos M.|last2=Wu|first2=Jiaping|last3=Xiao|first3=Xi|last4=Bruhn|first4=Annette|last5=Krause-Jensen|first5=Dorte|date=2017|title=Can Seaweed Farming Play a Role in Climate Change Mitigation and Adaptation?|journal=Frontiers in Marine Science|language=en|volume=4|doi=10.3389/fmars.2017.00100|issn=2296-7745|doi-access=free}}</ref> The IPCC [[Special Report on the Ocean and Cryosphere in a Changing Climate]] recommends "further research attention" as a mitigation tactic.<ref name=":2">{{Cite book|last1=Bindoff|first1=N. L.|title={{Harvnb|IPCC SROCC|2019}}|last2=Cheung|first2=W. W. L.|last3=Kairo|first3=J. G.|last4=Arístegui|first4=J.|last5=Guinder|first5=V. A.|last6=Hallberg|first6=R.|last7=Hilmi|first7=N. J. M.|last8=Jiao|first8=N.|last9=Karim|first9=Md S.|year=2019|pages=447–587|chapter=Chapter 5: Changing Ocean, Marine Ecosystems, and Dependent Communities|ref={{harvid|IPCC SROCC Ch5|2019}} <!-- ipcc:20200202 -->|display-authors=4|chapter-url=https://www.ipcc.ch/site/assets/uploads/sites/3/2019/11/09_SROCC_Ch05_FINAL.pdf|first10=L.|last16=Williamson|first16=P.|last15=Tagliabue|first15=A.|last14=Suga|last12=Purca Cuicapusa|last13=Rinkevich|first13=B.|first12=S. R.|last11=O'Donoghue|first11=S.|last10=Levin|first14=T.}}</ref>

Revision as of 04:16, 8 March 2021

Seaweed
Informal group of macroscopic marine algae
"Fucus serratus"
Fucus serratus
Scientific classification
Domain: Eukaryota
Seaweeds can be found in the following groups
Photo of seaweed with small swollen areas at the end of each frond
Ascophyllum nodosum exposed to the sun in Nova Scotia, Canada
Photo of detached seaweed frond lying on sand
Dead man's fingers (Codium fragile) off the Massachusetts coast in the United States
Photo of seaweed with the tip floating at the surface
The top of a kelp forest in Otago, New Zealand

Seaweed, or macroalgae, refers to thousands of species of macroscopic, multicellular, marine algae. The term includes some types of Rhodophyta (red), Phaeophyta (brown) and Chlorophyta (green) macroalgae. Seaweed species such as kelps provide essential nursery habitat for fisheries and other marine species and thus protect food sources; other species, such as planktonic algae, play a vital role in capturing carbon, producing up to 90% of Earth's oxygen.

Natural seaweed ecosystems are sometimes under threat from human activity. For example, mechanical dredging of kelp destroys the resource and dependent fisheries. Other forces also threaten some seaweed ecosystems; a wasting disease in predators of purple urchins has led to a urchin population surge which destroyed large kelp forest regions off the coast of California.[3]

Humans have a long history of cultivating seaweeds for their use. In recent years, seaweed farming has become a global agricultural practice, providing food, source material for various chemical uses (such as Carrageenan), cattle feeds and fertilizers. Because of their importance in marine ecologies and for absorbing carbon dioxide, recent attention has been on cultivating seaweeds as a potential climate change mitigation strategy for biosequestration of carbon dioxide, alongside other benefits like nutrient pollution reduction, increased habitat for coastal aquatic species, and reducing local ocean acidification.[4] The IPCC Special Report on the Ocean and Cryosphere in a Changing Climate recommends "further research attention" as a mitigation tactic.[5]

Taxonomy

"Seaweed" lacks a formal definition, but clearly indicates a requirement of association to the ocean, and visible to the naked eye. The term refers to both flowering plants submerged in the ocean, an example of which is eelgrass, but also refers to our larger marine algae. Generally it is one of several groups of multicellular algae: red, green and brown. They lack a common multicellular ancestor, forming a polyphyletic group. In addition, bluegreen algae (Cyanobacteria) are occasionally considered in seaweed literature. [6]

The number of seaweed species is still discussed among scientists, but most likely there are several thousand species of seaweed. [7]

Genera

Claudea elegans tetrasporangia

The following table lists a very few example genera of seaweed.

Genus Algae Phylum Remarks
Caulerpa Green Submerged
Fucus Brown In intertidal zones on rocky shores.
Gracilaria Red Cultivated for food
Laminaria Brown Also known as kelp, 8–30 m under water, cultivated for food.
Macrocystis Brown Giant kelp, forming floating canopies.
Monostroma Green
Porphyra Red Intertidal zones in temperate climate. Cultivated for food.
Sargassum Brown Pelagic especially in the Sargasso Sea.

Anatomy

Seaweed's appearance resembles non-arboreal terrestrial plants. Its anatomy includes:[8]

  • Thallus: algal body
    • Lamina or blade: flattened structure that is somewhat leaf-like
      • Sorus: spore cluster
      • pneumatocyst, air bladder: a flotation-assisting organ on the blade
      • Kelp, float: a flotation-assisting organ between the lamina and stipe
    • Stipe: stem-like structure, may be absent
    • Holdfast: basal structure providing attachment to a substrate
      • Haptera: finger-like extension of the holdfast that anchors to a benthic substrate

The stipe and blade are collectively known as the frond.

Ecology

Seaweed covers this rocky seabed on the east coast of Australia

Two environmental requirements dominate seaweed ecology. These are seawater (or at least brackish water) and light sufficient to support photosynthesis. Another common requirement is an attachment point, and therefore seaweed most commonly inhabits the littoral zone (nearshore waters) and within that zone, on rocky shores more than on sand or shingle. In addition, there are few genera (e.g., Sargassum and Gracilaria) which do not live attached to the sea floor, but float freely.

Seaweed occupies various ecological niches. At the surface, they are only wetted by the tops of sea spray, while some species may attach to a substrate several meters deep. In some areas, littoral seaweed colonies can extend miles out to sea.[citation needed] The deepest living seaweed are some species of red algae. Others have adapted to live in tidal rock pools. In this habitat, seaweed must withstand rapidly changing temperature and salinity and occasional drying.[9]

Macroalgae and macroalgal detritus have also been shown to be an important food source for benthic organisms, because macroalgae shed old fronds.[10] These macroalgal fronds tend to be utilized by benthos in the intertidal zone close to the shore.[11][12] Alternatively, pneumatocysts (gas filled “bubbles”) can keep the macroalgae thallus afloat fronds are transported by wind and currents from the coast into the deep ocean.[13] It has been shown that benthic organisms also at several 100 m tend to utilize these macroalgae remnants.[14]

As macroalgae takes up carbon dioxide and release oxygen in the photosynthesis, macroalgae fronds can also contribute to carbon sequestration in the ocean, when the macroalgal fronds drift offshore into the deep ocean basins and sink to the sea floor without being remineralized by organisms.[15] The importance of this process for the Blue Carbon storage is currently discussed among scientists.[16][17][18]

Production

As of 2018, the top 10 countries produced 96% of the global total of 2,165,675 metric tons.[19]

Seaweed production
Country Thousands metric tons
per year
China 699
France 617
United Kingdom 205
Japan 123
Chile 109
Philippines 96
North Korea 71
South Korea 67
Indonesia 47
Norway 41

Farming

Underwater Eucheuma farming in the Philippines
A seaweed farmer stands in shallow water, gathering edible seaweed that has grown on a rope
A seaweed farmer in Nusa Lembongan (Indonesia) gathers edible seaweed that has grown on a rope.

Seaweed farming or kelp farming is the practice of cultivating and harvesting seaweed. In its simplest form farmers gather from natural beds, while at the other extreme farmers fully control the crop's life cycle.

The seven most cultivated taxa are Eucheuma spp., Kappaphycus alvarezii, Gracilaria spp., Saccharina japonica, Undaria pinnatifida, Pyropia spp., and Sargassum fusiforme. Eucheuma and K. alvarezii are attractive for carrageenan (a gelling agent); Gracilaria is farmed for agar; the rest are eaten after limited processing.[20] Seaweeds are different from mangroves and seagrasses, as they are photosynthetic algal organisms[21] and are non-flowering.[20]

The largest seaweed-producing countries as of 2022 are China (58.62%) and Indonesia (28.6%); followed by South Korea (5.09%) and the Philippines (4.19%). Other notable producers include North Korea (1.6%), Japan (1.15%), Malaysia (0.53%), Zanzibar (Tanzania, 0.5%), and Chile (0.3%).[22][23] Seaweed farming has frequently been developed to improve economic conditions and to reduce fishing pressure.[24]

The Food and Agriculture Organization (FAO) reported that world production in 2019 was over 35 million tonnes. North America produced some 23,000 tonnes of wet seaweed. Alaska, Maine, France, and Norway each more than doubled their seaweed production since 2018. As of 2019, seaweed represented 30% of marine aquaculture.[25]

Seaweed farming is a carbon negative crop, with a high potential for climate change mitigation.[26][27] The IPCC Special Report on the Ocean and Cryosphere in a Changing Climate recommends "further research attention" as a mitigation tactic.[28] World Wildlife Fund, Oceans 2050, and The Nature Conservancy publicly support expanded seaweed cultivation.[25]

Uses

Seaweed has a variety of uses, for which it is farmed[29] or foraged.[30]

Food

Seaweed is consumed across the world, particularly in East Asia, e.g. Japan, China, Korea, Taiwan and Southeast Asia, e.g. Brunei, Singapore, Thailand, Burma, Cambodia, Vietnam, Indonesia, the Philippines, and Malaysia,[31] as well as in South Africa, Belize, Peru, Chile, the Canadian Maritimes, Scandinavia, South West England,[32] Ireland, Wales, Hawaii and California, and Scotland.

Gim (김, Korea), nori (海苔, Japan) and zicai (紫菜, China) are sheets of dried Porphyra used in soups, sushi or onigiri (rice balls). Chondrus crispus ('Irish moss' or carrageenan moss) is used in food additives, along with Kappaphycus and Gigartinoid seaweed. Porphyra is used in Wales to make laverbread (sometimes with oat flour). In northern Belize, seaweed is mixed with milk, nutmeg, cinnamon and vanilla to make "dulce" ("sweet").

Alginate, agar and carrageenan are gelatinous seaweed products collectively known as hydrocolloids or phycocolloids. Hydrocolloids are food additives.[33] The food industry exploits their gelling, water-retention, emulsifying and other physical properties. Agar is used in foods such as confectionery, meat and poultry products, desserts and beverages and moulded foods. Carrageenan is used in salad dressings and sauces, dietetic foods, and as a preservative in meat and fish, dairy items and baked goods.

Medicine and herbs

Photo of rocks covered by dried plant matter
Seaweed-covered rocks in the United Kingdom
Photo of a rock jetty covered with seaweed
Seaweed on rocks on Long Island

Alginates are used in wound dressings (see alginate dressing), and dental moulds. In microbiology, agar is used as a culture medium. Carrageenans, alginates and agaroses, with other macroalgal polysaccharides, have biomedicine applications. Delisea pulchra may interfere with bacterial colonization.[34] Sulfated saccharides from red and green algae inhibit some DNA and RNA-enveloped viruses.[35]

Seaweed extract is used in some diet pills.[36] Other seaweed pills exploit the same effect as gastric banding, expanding in the stomach to make the stomach feel more full.[37][38]

Edible packaging

Seaweed can also be used to produce edible packaging.

Bioremediation

Algae's strong photosynthesis creates a large affinity for nutrients; this allows the seaweed to be used to remove undesired nutrients from water (as for instance in dead zones). Seaweed also generates oxygen, which benefits hypoxic (=oxygen-poor) dead zones.[39] Nutrients such as ammonia, ammonium nitrate, nitrite, phosphate, iron, copper, as well as CO2 are rapidly consumed by growing seaweed. Reefs and lakes are naturally filtered this way (seaweed is consumed by fish and invertebrates), and this filtering process is duplicated in artificial seaweed filters such as algae scrubbers. China could remove its entire phosphorus effluent by increasing seaweed production by 150%.[40]

Modern floating algae scrubber/cultivator on a reef pond

Seaweed (macroalgae), as opposed to phytoplankton (microalgae), is used almost universally for filtration purposes because of the need to be able to easily remove (harvest) the algae from the water, which then removes the nutrients. Microalgae require more processing to separate from the water than macroalgae do; macroalgae is simply pulled out.

Marine species of Cladophora, Ulva (sea lettuce) and Chaetomorpha are preferred for filtration. Freshwater filtration applications commonly involve species such as Spirogyra.

Climate change

"Ocean afforestation” is a proposal for farming seaweed for carbon removal. After harvesting the seaweed decomposes into biogas, (60% methane and 40% carbon dioxide) in an anaerobic digester. The methane can be used as a biofuel, while the carbon dioxide can be stored to keep it from the atmosphere. Seaweed grows quickly and takes no space on land. Afforesting 9% of the ocean could sequester 53 billion tons of carbon dioxide annually (annual emissions are about 40 billion tons).[40]

The approach requires efficient techniques for growing and harvesting, efficient gas separation, and carbon capture and storage. The Advanced Research Projects Agency for Energy has a $22 million program called Macroalgae Research Inspiring Novel Energy Resources (MARINER) supporting innovations that could aid a seaweed industry.<, ref name=":1" />

Other uses

Other seaweed may be used as fertilizer, compost for landscaping, or to combat beach erosion through burial in beach dunes.[41]

Seaweed is under consideration as a potential source of bioethanol.[42][43]

Seaweed is lifted out of the top of algae scrubber/cultivator, to be discarded or used as food, fertilizer, or skin care

Alginates are used in industrial products such as paper coatings, adhesives, dyes, gels, explosives and in processes such as paper sizing, textile printing, hydro-mulching and drilling. Seaweed is an ingredient in toothpaste, cosmetics and paints. Seaweed is used for the production of bio yarn (a textile).[44]

Several of these resources can be obtained from seaweed through biorefining.

Seaweed collecting is the process of collecting, drying and pressing seaweed. It was a popular pastime in the Victorian era and remains a hobby today. In some emerging countries, Seaweed is harvested daily to support communities.

Women in Tanzania grow "Mwani" (seaweed in Swahili). The farms are made up of little sticks in neat rows in the warm, shallow water. Once they harvest the seaweed, it is used for many purposes: food, cosmetics, fabric, etc.

Seaweed is sometimes used to build roofs on houses on Læsø in Denmark[45]

Seaweeds are used as animal feeds. They have long been grazed by sheep, horses and cattle in Northern Europe. They are valued for fish production.[46] Adding seaweed to livestock feed can substantially reduce methane emissions from cattle.[47]

Health risks

Rotting seaweed is a potent source of hydrogen sulfide, a highly toxic gas, and has been implicated in some incidents of apparent hydrogen-sulphide poisoning.[48] It can cause vomiting and diarrhea.

The so-called "stinging seaweed" Microcoleus lyngbyaceus is a filamentous cyanobacteria which contains toxins including lyngbyatoxin-a and debromoaplysiatoxin. Direct skin contact can cause seaweed dermatitis characterized by painful, burning lesions that last for days.[1][49]

Threats

Bacterial disease ice-ice infects Kappaphycus (red seaweed), turning its branches white. The disease caused heavy crop losses in the Philippines, Tanzania and Mozambique.[40]

Sea urchin barrens have replaced kelp forests in multiple areas. They are “almost immune to starvation”. Lifespans can exceed 50 years. When stressed by hunger, their jaws and teeth enlarge, and they form "fronts" and hunt for food collectively.[40]

See also

References

  1. ^ a b https://www.cabdirect.org/cabdirect/abstract/19822902103 "Escharotic stomatitis caused by the "stinging seaweed" Microcoleus lyngbyaceus (formerly Lyngbya majuscula): case report and literature review"
  2. ^ James, William D.; Berger, Timothy G.; et al. (2006). Andrews' Diseases of the Skin: clinical Dermatology. Saunders Elsevier. ISBN 978-0-7216-2921-6.
  3. ^ "California's crashing kelp forest". phys.org. Retrieved 2021-02-24.
  4. ^ Duarte, Carlos M.; Wu, Jiaping; Xiao, Xi; Bruhn, Annette; Krause-Jensen, Dorte (2017). "Can Seaweed Farming Play a Role in Climate Change Mitigation and Adaptation?". Frontiers in Marine Science. 4. doi:10.3389/fmars.2017.00100. ISSN 2296-7745.
  5. ^ Bindoff, N. L.; Cheung, W. W. L.; Kairo, J. G.; Arístegui, J.; et al. (2019). "Chapter 5: Changing Ocean, Marine Ecosystems, and Dependent Communities" (PDF). IPCC SROCC 2019. pp. 447–587.
  6. ^ Lobban, Christopher S.; Harrison, Paul J. (1994). "Morphology, life histories, and morphogenesis". Seaweed Ecology and Physiology: 1–68. doi:10.1017/CBO9780511626210.002. ISBN 9780521408974.
  7. ^ Townsend, David W. (March 2012). Oceanography and Marine Biology: An Introduction to Marine Science. Oxford University Press Inc. ISBN 9780878936021.
  8. ^ "seaweed menu". www.easterncapescubadiving.co.za. Retrieved 2019-04-28.
  9. ^ Lewis, J. R. 1964. The Ecology of Rocky Shores. The English Universities Press Ltd.
  10. ^ Krause-Jensen, Dorte; Duarte, Carlos (2016). "Substantial role of macroalgae in marine carbon sequestration". Nature Geosci. 9 (10): 737–742. Bibcode:2016NatGe...9..737K. doi:10.1038/ngeo2790..
  11. ^ Dunton, K. H.; Schell, D. M. (1987). "Dependence of consumers on macroalgal (Laminaria solidungula) carbon in an arctic kelp community: δ13C evidence". Marine Biology. 93 (4): 615–625. doi:10.1007/BF00392799. S2CID 84714929.
  12. ^ Renaud, Paul E.; Løkken, Therese S.; Jørgensen, Lis L.; Berge, Jørgen; Johnson, Beverly J. (June 2015). "Macroalgal detritus and food-web subsidies along an Arctic fjord depth-gradient". Front. Mar. Sci. 2. doi:10.3389/fmars.2015.00031. S2CID 10417856. Retrieved September 21, 2020.
  13. ^ Krause-Jensen, Dorte; Duarte, Carlos (2016). "Substantial role of macroalgae in marine carbon sequestration". Nature Geosci. 9 (10): 737–742. Bibcode:2016NatGe...9..737K. doi:10.1038/ngeo2790.
  14. ^ Renaud, Paul E.; Løkken, Therese S.; Jørgensen, Lis L.; Berge, Jørgen; Johnson, Beverly J. (June 2015). "Macroalgal detritus and food-web subsidies along an Arctic fjord depth-gradient". Front. Mar. Sci. 2. doi:10.3389/fmars.2015.00031. S2CID 10417856. Retrieved September 21, 2020.
  15. ^ Krause-Jensen, Dorte; Duarte, Carlos (2016). "Substantial role of macroalgae in marine carbon sequestration". Nature Geosci. 9 (10): 737–742. Bibcode:2016NatGe...9..737K. doi:10.1038/ngeo2790..
  16. ^ Watanabe, Kenta; Yoshida, Goro; Hori, Masakazu; Umezawa, Yu; Moki, Hirotada; Kuwae, Tomohiro (May 2020). "Macroalgal metabolism and lateral carbon flows can create significant carbon sinks". Biogeosciences. 17 (9): 2425–2440. Bibcode:2020BGeo...17.2425W. doi:10.5194/bg-17-2425-2020. Retrieved September 21, 2020.
  17. ^ Krause-Jensen, Dorte; Lavery, Paul; Serrano, Oscar; Marbà, Núria; Masque, Pere; Duarte, Carlos M. (June 2018). "Sequestration of macroalgal carbon: the elephant in the Blue Carbon room". The Royal Society Publishing. 14 (6). doi:10.1098/rsbl.2018.0236. PMC 6030603. PMID 29925564. Retrieved September 21, 2020.
  18. ^ Ortega, Alejandra; Geraldi, Nathan R.; Alam, Intikhab; Kamau, Allan A.; Acinas, Silvia G; Logares, Ramiro; Gasol, Josep M; Massana, Ramon; Krause-Jensen, Dorte; Duarte, Carlos M (2019). "Important contribution of macroalgae to oceanic carbon sequestration". Nature Geoscience. 12 (9): 748–754. Bibcode:2019NatGe..12..748O. doi:10.1038/s41561-019-0421-8. hdl:10754/656768. S2CID 199448971.
  19. ^ "Volume of seaweed production ranked by country". surialink.seaplant.net. Retrieved 2019-04-28.
  20. ^ a b Reynolds, Daman; Caminiti, Jeff; Edmundson, Scott; Gao, Song; Wick, Macdonald; Huesemann, Michael (2022-07-12). "Seaweed proteins are nutritionally valuable components in the human diet". The American Journal of Clinical Nutrition. 116 (4): 855–861. doi:10.1093/ajcn/nqac190. ISSN 0002-9165. PMID 35820048.
  21. ^ "Seaweeds: Plants or Algae?". Point Reyes National Seashore Association. Retrieved 1 December 2018.
  22. ^ Zhang, Lizhu; Liao, Wei; Huang, Yajun; Wen, Yuxi; Chu, Yaoyao; Zhao, Chao (13 October 2022). "Global seaweed farming and processing in the past 20 years". Food Production, Processing and Nutrition. 4 (1). doi:10.1186/s43014-022-00103-2.
  23. ^ Buschmann, Alejandro H.; Camus, Carolina; Infante, Javier; Neori, Amir; Israel, Álvaro; Hernández-González, María C.; Pereda, Sandra V.; Gomez-Pinchetti, Juan Luis; Golberg, Alexander; Tadmor-Shalev, Niva; Critchley, Alan T. (2 October 2017). "Seaweed production: overview of the global state of exploitation, farming and emerging research activity". European Journal of Phycology. 52 (4): 391–406. Bibcode:2017EJPhy..52..391B. doi:10.1080/09670262.2017.1365175. ISSN 0967-0262. S2CID 53640917.
  24. ^ Ask, E.I (1990). Cottonii and Spinosum Cultivation Handbook. Philippines: FMC BioPolymer Corporation. p. 52.
  25. ^ a b Jones, Nicola (March 15, 2023). "Banking on the Seaweed Rush". Hakai Magazine. Retrieved 2023-03-19.
  26. ^ Wang, Taiping; Yang, Zhaoqing; Davis, Jonathan; Edmundson, Scott J. (2022-05-01). Quantifying Nitrogen Bioextraction by Seaweed Farms – A Real-time Modeling-Monitoring Case Study in Hood Canal, WA (Technical report). Office of Scientific and Technical Information. doi:10.2172/1874372.
  27. ^ Duarte, Carlos M.; Wu, Jiaping; Xiao, Xi; Bruhn, Annette; Krause-Jensen, Dorte (2017). "Can Seaweed Farming Play a Role in Climate Change Mitigation and Adaptation?". Frontiers in Marine Science. 4. doi:10.3389/fmars.2017.00100. hdl:10754/623247. ISSN 2296-7745.
  28. ^ Bindoff, N. L.; Cheung, W. W. L.; Kairo, J. G.; Arístegui, J.; et al. (2019). "Chapter 5: Changing Ocean, Marine Ecosystems, and Dependent Communities" (PDF). IPCC Special Report on the Ocean and Cryosphere in a Changing Climate. pp. 447–587.
  29. ^ "Seaweed farmers get better prices if united". Sun.Star. 2008-06-19. Archived from the original on 2008-09-09. Retrieved 2008-07-16.
  30. ^ "Springtime's foraging treats". The Guardian. London. 2007-01-06. Retrieved 2008-07-16.
  31. ^ Mohammad, Salma (4 Jan 2020). "Application of seaweed (Kappaphycus alvarezii) in Malaysian food products". International Food Research Journal. 26: 1677–1687.
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Further reading