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Biomass (ecology)

February 15, 2024

This article is about the ecological measure. For the renewable energy source, see biomass (energy).

Biomass is the mass of living biological organisms in a given area or ecosystem at a given time. Biomass can refer to species biomass, which is the mass of one or more species, or to community biomass, which is the mass of all species in the community. It can include microorganisms, plants or animals.[3] The mass can be expressed as the average mass per unit area, or as the total mass in the community.

The total global live biomass has been estimated at about 550 billion tonnes carbon,[1] most of which is found in forests.
Shallow aquatic environments, such as wetlands, estuaries and coral reefs, can be as productive as forests, generating similar amounts of new biomass each year on a given area.[2]

How biomass is measured depends on why it is being measured. Sometimes, the biomass is regarded as the natural mass of organisms in situ, just as they are. For example, in a salmon fishery, the salmon biomass might be regarded as the total wet weight the salmon would have if they were taken out of the water. In other contexts, biomass can be measured in terms of the dried organic mass, so perhaps only 30% of the actual weight might count, the rest being water. For other purposes, only biological tissues count, and teeth, bones and shells are excluded. In some applications, biomass is measured as the mass of organically bound carbon (C) that is present.

In 2018, Bar-On et al. estimated the total live biomass on Earth at about 550 billion (5.5×1011) tonnes C,[1] most of it in plants. In 1998 Field et.al. estimated the total annual net primary production of biomass at just over 100 billion tonnes C/yr.[4] The total live biomass of bacteria was once thought to be about the same as plants,[5] but recent studies suggest it is significantly less.[1][6][7][8][9] The total number of DNA base pairs on Earth, as a possible approximation of global biodiversity, is estimated at (5.3±3.6)×1037, and weighs 50 billion tonnes.[10][11] Anthropogenic mass (human-made material) is expected to exceed all living biomass on earth at around the year 2020.[12]

Ecological pyramids edit

 
An energy pyramid illustrates how much energy is needed as it flows upward to support the next trophic level. Only about 10% of the energy transferred between each trophic level is converted to biomass.
Main article: Ecological pyramid

An ecological pyramid is a graphical representation that shows, for a given ecosystem, the relationship between biomass or biological productivity and trophic levels.

  • A biomass pyramid shows the amount of biomass at each trophic level.
  • A productivity pyramid shows the production or turn-over in biomass at each trophic level.

An ecological pyramid provides a snapshot in time of an ecological community.

The bottom of the pyramid represents the primary producers (autotrophs). The primary producers take energy from the environment in the form of sunlight or inorganic chemicals and use it to create energy-rich molecules such as carbohydrates. This mechanism is called primary production. The pyramid then proceeds through the various trophic levels to the apex predators at the top.

When energy is transferred from one trophic level to the next, typically only ten percent is used to build new biomass. The remaining ninety percent goes to metabolic processes or is dissipated as heat. This energy loss means that productivity pyramids are never inverted, and generally limits food chains to about six levels. However, in oceans, biomass pyramids can be wholly or partially inverted, with more biomass at higher levels.

Terrestrial biomass edit

 
     Relative terrestrial biomasses
of vertebrates versus arthropods

Terrestrial biomass generally decreases markedly at each higher trophic level (plants, herbivores, carnivores). Examples of terrestrial producers are grasses, trees and shrubs. These have a much higher biomass than the animals that consume them, such as deer, zebras and insects. The level with the least biomass are the highest predators in the food chain, such as foxes and eagles.

In a temperate grassland, grasses and other plants are the primary producers at the bottom of the pyramid. Then come the primary consumers, such as grasshoppers, voles and bison, followed by the secondary consumers, shrews, hawks and small cats. Finally the tertiary consumers, large cats and wolves. The biomass pyramid decreases markedly at each higher level.

Changes in plant species in the terrestrial ecosystem can result in changes in the biomass of soil decomposer communities.[13] Biomass in C3 and C4 plant species can change in response to altered concentrations of CO2.[14] C3 plant species have been observed to increase in biomass in response to increasing concentrations of CO2 of up to 900 ppm.[15]

Ocean biomass edit

See also: Marine life

Ocean or marine biomass, in a reversal of terrestrial biomass, can increase at higher trophic levels. In the ocean, the food chain typically starts with phytoplankton, and follows the course:

Phytoplankton → zooplankton → predatory zooplankton → filter feeders → predatory fish

 
Ocean food web showing a network of food chains
 
Biomass pyramids
Compared to terrestrial biomass pyramids, aquatic pyramids are inverted at the base
 
Prochlorococcus, an influential bacterium

Phytoplankton are the main primary producers at the bottom of the marine food chain. Phytoplankton use photosynthesis to convert inorganic carbon into protoplasm. They are then consumed by zooplankton that range in size from a few micrometers in diameter in the case of protistan microzooplankton to macroscopic gelatinous and crustacean zooplankton.

Zooplankton comprise the second level in the food chain, and includes small crustaceans, such as copepods and krill, and the larva of fish, squid, lobsters and crabs.

In turn, small zooplankton are consumed by both larger predatory zooplankters, such as krill, and by forage fish, which are small, schooling, filter-feeding fish. This makes up the third level in the food chain.

A fourth trophic level can consist of predatory fish, marine mammals and seabirds that consume forage fish. Examples are swordfish, seals and gannets.

Apex predators, such as orcas, which can consume seals, and shortfin mako sharks, which can consume swordfish, make up a fifth trophic level. Baleen whales can consume zooplankton and krill directly, leading to a food chain with only three or four trophic levels.

Marine environments can have inverted biomass pyramids. In particular, the biomass of consumers (copepods, krill, shrimp, forage fish) is larger than the biomass of primary producers. This happens because the ocean's primary producers are tiny phytoplankton which are r-strategists that grow and reproduce rapidly, so a small mass can have a fast rate of primary production. In contrast, terrestrial primary producers, such as forests, are K-strategists that grow and reproduce slowly, so a much larger mass is needed to achieve the same rate of primary production.

Among the phytoplankton at the base of the marine food web are members from a phylum of bacteria called cyanobacteria. Marine cyanobacteria include the smallest known photosynthetic organisms. The smallest of all, Prochlorococcus, is just 0.5 to 0.8 micrometres across.[16] In terms of individual numbers, Prochlorococcus is possibly the most plentiful species on Earth: a single millilitre of surface seawater can contain 100,000 cells or more. Worldwide, there are estimated to be several octillion (1027) individuals.[17] Prochlorococcus is ubiquitous between 40°N and 40°S and dominates in the oligotrophic (nutrient poor) regions of the oceans.[18] The bacterium accounts for an estimated 20% of the oxygen in the Earth's atmosphere, and forms part of the base of the ocean food chain.[19]

Bacterial biomass edit

Bacteria and archaea are both classified as prokaryotes, and their biomass is commonly estimated together. The global biomass of prokaryotes is estimated at about 30 billion tonnes C,[20] dominated by bacteria.[1]

Geographic location Number of cells (× 1029) Billion tonnes of carbon
Open ocean
1.2[1][5]
1.6[1] to 2.2[5]
Ocean subsurface
5[20]
10[20]
Terrestrial soil
3[1]
8[1]
Terrestrial subsurface
2 to 6[20]
4 to 12[20]
Total
11 to 15[20]
23 to 31[20]

The estimates for the global biomass of prokaryotes had changed significantly over recent decades, as more data became available. A much-cited study from 1998[5] collected data on abundances (number of cells) of bacteria and archaea in different natural environments, and estimated their total biomass at 350 to 550 billion tonnes C. This vast amount is similar to the biomass of carbon in all plants.[1][5] The vast majority of bacteria and archaea were estimated to be in sediments deep below the seafloor or in the deep terrestrial biosphere (in deep continental aquifers). However, updated measurements reported in a 2012 study[6] reduced the calculated prokaryotic biomass in deep subseafloor sediments from the original ≈300 billion tonnes C to ≈4 billion tonnes C (range 1.5-22 billion tonnes). This update originates from much lower estimates of both the prokaryotic abundance and their average weight.

A census published in PNAS in May 2018 estimated global bacterial biomass at ≈70 billion tonnes C, of which ≈60 billion tonnes are in the terrestrial deep subsurface.[1] It also estimated the global biomass of archaea at ≈7 billion tonnes C. A later study by the Deep Carbon Observatory published in 2018 reported a much larger dataset of measurements, and updated the total biomass estimate in the deep terrestrial biosphere. It used this new knowledge and previous estimates to update the global biomass of bacteria and archaea to 23 - 31 billion tonnes C.[20] Roughly 70% of the global biomass was estimated to be found in the deep subsurface.[7][21] The estimated number of prokaryotic cells globally was estimated to be 11-15 × 1029.[20] With this information, the authors of the May 2018 PNAS article[1] revised their estimate for the global biomass of prokaryotes to ≈30 billion tonnes C,[22] similar to the Deep Carbon Observatory estimate.[20]

These estimates convert global abundance of prokaryotes into global biomass using average cellular biomass figures that are based on limited data. Recent estimates used an average cellular biomass of about 20-30 femtogram carbon (fgC) per cell in the subsurface and terrestrial habitats.[1][20][23]

Global biomass edit

External image
  Visualizing the biomass of life

The total global biomass has been estimated at about 550 billion tonnes C. [24][1] A breakdown of the global biomass is given by kingdom in the table below, based on a 2018 study by Bar-On et. al.[1]

Kingdom Global biomass in billion tonnes of carbon Global dry biomass in billion tonnes Global wet biomass in billion tonnes Image
Plantae
450[1]
900
2700
 
Bacteria + Archaea
30[20][22]
60
200
 
Fungi
12[1]
24
80
 
Protista
4[1]
8
25
 
Animalia
2[1]
4
13
 
Total
500
1000
3000
 
Humans and their livestock represent 96% of all mammals on earth in terms of biomass, whereas all wild mammals represent only 4%.[1]

Animals represent less than 0.5% of the total biomass on Earth, with about 2 billion tonnes C in total. Most animal biomass is found in the oceans, where arthropods, such as copepods, account for about 1 billion tonnes C and fish for another 0.7 billion tonnes C.[1] Roughly half of the biomass of fish in the world are mesopelagic, such as lanternfish,[25] spending most of the day in the deep, dark waters.[26] Marine mammals such as whales and dolphins account for about 0.006 billion tonnes C.[27]


Land animals account for about 500 million tonnes C, or about 20% of the biomass of animals on Earth.[1] Terrestrial arthropods account for about 150 million tonnes C, most of which is found in the topsoil.[28] Land mammals account for about 180 million tonnes C, most of which are humans (about 80 million tonnes C) and domesticated mammals (about 90 million tonnes C). Wild terrestrial mammals account for only about 3 million tonnes C, less than 2% of the total mammalian biomass on land.[27]

 
The global biomass broken down by kingdom and into taxonomic groups for animals.[1] The estimates for bacteria and archaea have been updated to 30 billion tonnes C combined since this figure was made.[20]

Most of the global biomass is found on land, with only 5 to 10 billion tonnes C found in the oceans.[24] On land, there is about 1,000 times more plant biomass (phytomass) than animal biomass (zoomass).[29] About 18% of this plant biomass is eaten by the land animals.[30] However, marine animals eat most of the marine autotrophs, and the biomass of marine animals is greater than that of marine autotrophs. [1][30]

According to a 2020 study published in Nature, human-made materials, or anthropogenic mass, outweigh all living biomass on earth, with plastic alone exceeding the mass of all land and marine animals combined.[31][12][32]

name number of species date of estimate individual count mean living mass of individual percent biomass (dried) global dry biomass in million tonnes global wet (fresh) biomass in million tonnes
Terrestrial
Humans
1
November 2022
8 billion[33]
50 kg
(incl children)[34]
40%[35]
160
400[27]
2005
4.63 billion adults
62 kg
(excl. children)[36]
287[36]
Cattle
1
2021
1.5 billion[37]
300 kg
30%
125
416[27]
Sheep
1
2021
1.3 billion[37]
30 kg
30%
12
39[27]
Goats
1
2021
1.1 billion[37]
30 kg
30%
10
32[27]
Chickens
1
2021
26 billion
0.9 kg for broilers, 1.8 kg for layers[38]
30%
8[1]
25
Ants
15,700[39]
2022
20-90×1015[39]
3.7 mg[28]-5.5 mg[39]
22.8%[40]
10–100[39]
40-450
Earthworms
7,000-30,000[41]
2016
10 mg (dry weight)[42]
10-25%[43]
400[1]
1,600
Termites
2,972[citation needed]
2022
2 mg[40]
27%[40]
100[28][44]
440[45]
Nematodes
2019
4.4×1020[46]
20%[40]
 60
300[46]
Marine
Blue whales[47]
1
Pre-whaling
340,000
40%[48]
36
2023
50,000[27]
60,000 kg
40%[48]
1.2
3[27]
Fish
>20,000[49]
2022
30%[50]
3,000
9,000[26]
Antarctic krill
1
2008
7.8×1014[51]
0.486 g[51]
379 (in peak season)[51]
Copepods
(a zooplankton)
13,000
10−6–10−9 kg
Cyanobacteria
(a picoplankton)
?
2003
1,000[52]

Global rate of production edit

 
Globally, terrestrial and oceanic habitats produce a similar amount of new biomass each year (56.4 billion tonnes C terrestrial and 48.5 billion tonnes C oceanic).

Net primary production is the rate at which new biomass is generated, mainly due to photosynthesis. Global primary production can be estimated from satellite observations. Satellites scan the normalised difference vegetation index (NDVI) over terrestrial habitats, and scan sea-surface chlorophyll levels over oceans. This results in 56.4 billion tonnes C/yr (53.8%), for terrestrial primary production, and 48.5 billion tonnes C/yr for oceanic primary production.[4] Thus, the total photoautotrophic primary production for the Earth is about 104.9 billion tonnes C/yr. This translates to about 426 gC/m2/yr for land production (excluding areas with permanent ice cover), and 140 gC/m2/yr for the oceans.

However, there is a much more significant difference in standing stocks—while accounting for almost half of total annual production, oceanic autotrophs account for only about 0.2% of the total biomass.

Terrestrial freshwater ecosystems generate about 1.5% of the global net primary production.[53]

Some global producers of biomass in order of productivity rates are

Producer Biomass productivity
(gC/m2/yr) 		Ref Total area
(million km2) 		Ref Total production
(billion tonnes C/yr)
Swamps and marshes 2,500 [2] 5.7 [54]
Tropical rainforests 2,000 [55] 8 16
Coral reefs 2,000 [2] 0.28 [56] 0.56
Algal beds 2,000 [2]
River estuaries 1,800 [2]
Temperate forests 1,250 [2] 19 24
Cultivated lands 650 [2][57] 17 11
Tundras 140 [2][57] 11.5-29.8 [58][59]
Open ocean 125 [2][57] 311 39
Deserts 3 [57] 50 0.15

See also edit

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  49. ^ Fisheries, NOAA (3 May 2022). "Fun Facts About Fascinating Fish | NOAA Fisheries". NOAA. Retrieved 30 July 2023.
  50. ^ Johnson, Brett M.; Pate, William M.; Hansen, Adam G. (2017). "Energy Density and Dry Matter Content in Fish: New Observations and an Evaluation of Some Empirical Models". Transactions of the American Fisheries Society. 146 (6): 1262–1278. doi:10.1080/00028487.2017.1360392.
  51. ^ a b c Atkinson A, Siegel V, Pakhomov EA, Jessopp MJ, Loeb V (2009). "A re-appraisal of the total biomass and annual production of Antarctic krill" (PDF). Deep-Sea Research Part I. 56 (5): 727–740. Bibcode:2009DSRI...56..727A. doi:10.1016/j.dsr.2008.12.007.
  52. ^ Garcia-Pichel F, Belnap J, Neuer S, Schanz F (2003). "Estimates of global cyanobacterial biomass and its distribution" (PDF). Algological Studies. 109: 213–217. doi:10.1127/1864-1318/2003/0109-0213.
  53. ^ Alexander DE (1 May 1999). Encyclopedia of Environmental Science. Springer. ISBN 978-0-412-74050-3.
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  56. ^ Mark Spalding, Corinna Ravilious, and Edmund Green. 2001. World Atlas of Coral Reefs. Berkeley, California: University of California Press and UNEP/WCMC.
  57. ^ a b c d Park CC (2001). The environment: principles and applications (2nd ed.). Routledge. p. 564. ISBN 978-0-415-21770-5.
  58. ^ "Tundra - Biomes - WWF". World Wildlife Fund. Retrieved 5 October 2021.
  59. ^ "Tundra". ArcGIS StoryMaps. 17 January 2020. Retrieved 5 October 2021. the tundra is a vast and treeless land which covers about 20% of the Earth's surface, circumnavigating the North pole.

Further reading edit

  • Foley JA, Monfreda C, Ramankutty N, Zaks D (July 2007). "Our share of the planetary pie". Proceedings of the National Academy of Sciences of the United States of America. 104 (31): 12585–6. Bibcode:2007PNAS..10412585F. doi:10.1073/pnas.0705190104. PMC 1937509. PMID 17646656.
  • Haberl H, Erb KH, Krausmann F, Gaube V, Bondeau A, Plutzar C, Gingrich S, Lucht W, Fischer-Kowalski M (July 2007). "Quantifying and mapping the human appropriation of net primary production in earth's terrestrial ecosystems". Proceedings of the National Academy of Sciences of the United States of America. 104 (31): 12942–7. Bibcode:2007PNAS..10412942H. doi:10.1073/pnas.0704243104. PMC 1911196. PMID 17616580.
  • Purves WK, Orians GH (2007). Life: The Science of Biology (8th ed.). W. H. Freeman. ISBN 978-1-4292-0877-2.

External links edit

 
Look up biomass in Wiktionary, the free dictionary.
  • The mass of all life on Earth is staggering — until you consider how much we’ve lost
  • Counting bacteria 12 December 2013 at the Wayback Machine

February 15, 2024
biomass, ecology, this, article, about, ecological, measure, renewable, energy, source, biomass, energy, biomass, mass, living, biological, organisms, given, area, ecosystem, given, time, biomass, refer, species, biomass, which, mass, more, species, community,. This article is about the ecological measure For the renewable energy source see biomass energy Biomass is the mass of living biological organisms in a given area or ecosystem at a given time Biomass can refer to species biomass which is the mass of one or more species or to community biomass which is the mass of all species in the community It can include microorganisms plants or animals 3 The mass can be expressed as the average mass per unit area or as the total mass in the community The total global live biomass has been estimated at about 550 billion tonnes carbon 1 most of which is found in forests Shallow aquatic environments such as wetlands estuaries and coral reefs can be as productive as forests generating similar amounts of new biomass each year on a given area 2 How biomass is measured depends on why it is being measured Sometimes the biomass is regarded as the natural mass of organisms in situ just as they are For example in a salmon fishery the salmon biomass might be regarded as the total wet weight the salmon would have if they were taken out of the water In other contexts biomass can be measured in terms of the dried organic mass so perhaps only 30 of the actual weight might count the rest being water For other purposes only biological tissues count and teeth bones and shells are excluded In some applications biomass is measured as the mass of organically bound carbon C that is present In 2018 Bar On et al estimated the total live biomass on Earth at about 550 billion 5 5 1011 tonnes C 1 most of it in plants In 1998 Field et al estimated the total annual net primary production of biomass at just over 100 billion tonnes C yr 4 The total live biomass of bacteria was once thought to be about the same as plants 5 but recent studies suggest it is significantly less 1 6 7 8 9 The total number of DNA base pairs on Earth as a possible approximation of global biodiversity is estimated at 5 3 3 6 1037 and weighs 50 billion tonnes 10 11 Anthropogenic mass human made material is expected to exceed all living biomass on earth at around the year 2020 12 Contents 1 Ecological pyramids 2 Terrestrial biomass 3 Ocean biomass 4 Bacterial biomass 5 Global biomass 6 Global rate of production 7 See also 8 References 9 Further reading 10 External linksEcological pyramids edit nbsp An energy pyramid illustrates how much energy is needed as it flows upward to support the next trophic level Only about 10 of the energy transferred between each trophic level is converted to biomass Main article Ecological pyramid An ecological pyramid is a graphical representation that shows for a given ecosystem the relationship between biomass or biological productivity and trophic levels A biomass pyramid shows the amount of biomass at each trophic level A productivity pyramid shows the production or turn over in biomass at each trophic level An ecological pyramid provides a snapshot in time of an ecological community The bottom of the pyramid represents the primary producers autotrophs The primary producers take energy from the environment in the form of sunlight or inorganic chemicals and use it to create energy rich molecules such as carbohydrates This mechanism is called primary production The pyramid then proceeds through the various trophic levels to the apex predators at the top When energy is transferred from one trophic level to the next typically only ten percent is used to build new biomass The remaining ninety percent goes to metabolic processes or is dissipated as heat This energy loss means that productivity pyramids are never inverted and generally limits food chains to about six levels However in oceans biomass pyramids can be wholly or partially inverted with more biomass at higher levels Terrestrial biomass edit nbsp Relative terrestrial biomassesof vertebrates versus arthropodsTerrestrial biomass generally decreases markedly at each higher trophic level plants herbivores carnivores Examples of terrestrial producers are grasses trees and shrubs These have a much higher biomass than the animals that consume them such as deer zebras and insects The level with the least biomass are the highest predators in the food chain such as foxes and eagles In a temperate grassland grasses and other plants are the primary producers at the bottom of the pyramid Then come the primary consumers such as grasshoppers voles and bison followed by the secondary consumers shrews hawks and small cats Finally the tertiary consumers large cats and wolves The biomass pyramid decreases markedly at each higher level Changes in plant species in the terrestrial ecosystem can result in changes in the biomass of soil decomposer communities 13 Biomass in C3 and C4 plant species can change in response to altered concentrations of CO2 14 C3 plant species have been observed to increase in biomass in response to increasing concentrations of CO2 of up to 900 ppm 15 Ocean biomass editSee also Marine life Ocean or marine biomass in a reversal of terrestrial biomass can increase at higher trophic levels In the ocean the food chain typically starts with phytoplankton and follows the course Phytoplankton zooplankton predatory zooplankton filter feeders predatory fish nbsp Ocean food web showing a network of food chains nbsp Biomass pyramidsCompared to terrestrial biomass pyramids aquatic pyramids are inverted at the base nbsp Prochlorococcus an influential bacteriumPhytoplankton are the main primary producers at the bottom of the marine food chain Phytoplankton use photosynthesis to convert inorganic carbon into protoplasm They are then consumed by zooplankton that range in size from a few micrometers in diameter in the case of protistan microzooplankton to macroscopic gelatinous and crustacean zooplankton Zooplankton comprise the second level in the food chain and includes small crustaceans such as copepods and krill and the larva of fish squid lobsters and crabs In turn small zooplankton are consumed by both larger predatory zooplankters such as krill and by forage fish which are small schooling filter feeding fish This makes up the third level in the food chain A fourth trophic level can consist of predatory fish marine mammals and seabirds that consume forage fish Examples are swordfish seals and gannets Apex predators such as orcas which can consume seals and shortfin mako sharks which can consume swordfish make up a fifth trophic level Baleen whales can consume zooplankton and krill directly leading to a food chain with only three or four trophic levels Marine environments can have inverted biomass pyramids In particular the biomass of consumers copepods krill shrimp forage fish is larger than the biomass of primary producers This happens because the ocean s primary producers are tiny phytoplankton which are r strategists that grow and reproduce rapidly so a small mass can have a fast rate of primary production In contrast terrestrial primary producers such as forests are K strategists that grow and reproduce slowly so a much larger mass is needed to achieve the same rate of primary production Among the phytoplankton at the base of the marine food web are members from a phylum of bacteria called cyanobacteria Marine cyanobacteria include the smallest known photosynthetic organisms The smallest of all Prochlorococcus is just 0 5 to 0 8 micrometres across 16 In terms of individual numbers Prochlorococcus is possibly the most plentiful species on Earth a single millilitre of surface seawater can contain 100 000 cells or more Worldwide there are estimated to be several octillion 1027 individuals 17 Prochlorococcus is ubiquitous between 40 N and 40 S and dominates in the oligotrophic nutrient poor regions of the oceans 18 The bacterium accounts for an estimated 20 of the oxygen in the Earth s atmosphere and forms part of the base of the ocean food chain 19 Bacterial biomass editBacteria and archaea are both classified as prokaryotes and their biomass is commonly estimated together The global biomass of prokaryotes is estimated at about 30 billion tonnes C 20 dominated by bacteria 1 Geographic location Number of cells 1029 Billion tonnes of carbonOpen ocean 1 2 1 5 1 6 1 to 2 2 5 Ocean subsurface 5 20 10 20 Terrestrial soil 3 1 8 1 Terrestrial subsurface 2 to 6 20 4 to 12 20 Total 11 to 15 20 23 to 31 20 The estimates for the global biomass of prokaryotes had changed significantly over recent decades as more data became available A much cited study from 1998 5 collected data on abundances number of cells of bacteria and archaea in different natural environments and estimated their total biomass at 350 to 550 billion tonnes C This vast amount is similar to the biomass of carbon in all plants 1 5 The vast majority of bacteria and archaea were estimated to be in sediments deep below the seafloor or in the deep terrestrial biosphere in deep continental aquifers However updated measurements reported in a 2012 study 6 reduced the calculated prokaryotic biomass in deep subseafloor sediments from the original 300 billion tonnes C to 4 billion tonnes C range 1 5 22 billion tonnes This update originates from much lower estimates of both the prokaryotic abundance and their average weight A census published in PNAS in May 2018 estimated global bacterial biomass at 70 billion tonnes C of which 60 billion tonnes are in the terrestrial deep subsurface 1 It also estimated the global biomass of archaea at 7 billion tonnes C A later study by the Deep Carbon Observatory published in 2018 reported a much larger dataset of measurements and updated the total biomass estimate in the deep terrestrial biosphere It used this new knowledge and previous estimates to update the global biomass of bacteria and archaea to 23 31 billion tonnes C 20 Roughly 70 of the global biomass was estimated to be found in the deep subsurface 7 21 The estimated number of prokaryotic cells globally was estimated to be 11 15 1029 20 With this information the authors of the May 2018 PNAS article 1 revised their estimate for the global biomass of prokaryotes to 30 billion tonnes C 22 similar to the Deep Carbon Observatory estimate 20 These estimates convert global abundance of prokaryotes into global biomass using average cellular biomass figures that are based on limited data Recent estimates used an average cellular biomass of about 20 30 femtogram carbon fgC per cell in the subsurface and terrestrial habitats 1 20 23 Global biomass editExternal image nbsp Visualizing the biomass of lifeThe total global biomass has been estimated at about 550 billion tonnes C 24 1 A breakdown of the global biomass is given by kingdom in the table below based on a 2018 study by Bar On et al 1 Kingdom Global biomass in billion tonnes of carbon Global dry biomass in billion tonnes Global wet biomass in billion tonnes ImagePlantae 450 1 900 2700 nbsp Bacteria Archaea 30 20 22 60 200 nbsp Fungi 12 1 24 80 nbsp Protista 4 1 8 25 nbsp Animalia 2 1 4 13 nbsp Total 500 1000 3000 nbsp Humans and their livestock represent 96 of all mammals on earth in terms of biomass whereas all wild mammals represent only 4 1 Animals represent less than 0 5 of the total biomass on Earth with about 2 billion tonnes C in total Most animal biomass is found in the oceans where arthropods such as copepods account for about 1 billion tonnes C and fish for another 0 7 billion tonnes C 1 Roughly half of the biomass of fish in the world are mesopelagic such as lanternfish 25 spending most of the day in the deep dark waters 26 Marine mammals such as whales and dolphins account for about 0 006 billion tonnes C 27 Land animals account for about 500 million tonnes C or about 20 of the biomass of animals on Earth 1 Terrestrial arthropods account for about 150 million tonnes C most of which is found in the topsoil 28 Land mammals account for about 180 million tonnes C most of which are humans about 80 million tonnes C and domesticated mammals about 90 million tonnes C Wild terrestrial mammals account for only about 3 million tonnes C less than 2 of the total mammalian biomass on land 27 nbsp The global biomass broken down by kingdom and into taxonomic groups for animals 1 The estimates for bacteria and archaea have been updated to 30 billion tonnes C combined since this figure was made 20 Most of the global biomass is found on land with only 5 to 10 billion tonnes C found in the oceans 24 On land there is about 1 000 times more plant biomass phytomass than animal biomass zoomass 29 About 18 of this plant biomass is eaten by the land animals 30 However marine animals eat most of the marine autotrophs and the biomass of marine animals is greater than that of marine autotrophs 1 30 According to a 2020 study published in Nature human made materials or anthropogenic mass outweigh all living biomass on earth with plastic alone exceeding the mass of all land and marine animals combined 31 12 32 name number of species date of estimate individual count mean living mass of individual percent biomass dried global dry biomass in million tonnes global wet fresh biomass in million tonnesTerrestrial Humans 1 November 2022 8 billion 33 50 kg incl children 34 40 35 160 400 27 2005 4 63 billion adults 62 kg excl children 36 287 36 Cattle 1 2021 1 5 billion 37 300 kg 30 125 416 27 Sheep 1 2021 1 3 billion 37 30 kg 30 12 39 27 Goats 1 2021 1 1 billion 37 30 kg 30 10 32 27 Chickens 1 2021 26 billion 0 9 kg for broilers 1 8 kg for layers 38 30 8 1 25Ants 15 700 39 2022 20 90 1015 39 3 7 mg 28 5 5 mg 39 22 8 40 10 100 39 40 450Earthworms 7 000 30 000 41 2016 10 mg dry weight 42 10 25 43 400 1 1 600Termites 2 972 citation needed 2022 2 mg 40 27 40 100 28 44 440 45 Nematodes 2019 4 4 1020 46 20 40 60 300 46 Marine Blue whales 47 1 Pre whaling 340 000 40 48 362023 50 000 27 60 000 kg 40 48 1 2 3 27 Fish gt 20 000 49 2022 30 50 3 000 9 000 26 Antarctic krill 1 2008 7 8 1014 51 0 486 g 51 379 in peak season 51 Copepods a zooplankton 13 000 10 6 10 9 kgCyanobacteria a picoplankton 2003 1 000 52 Global rate of production edit nbsp Globally terrestrial and oceanic habitats produce a similar amount of new biomass each year 56 4 billion tonnes C terrestrial and 48 5 billion tonnes C oceanic Net primary production is the rate at which new biomass is generated mainly due to photosynthesis Global primary production can be estimated from satellite observations Satellites scan the normalised difference vegetation index NDVI over terrestrial habitats and scan sea surface chlorophyll levels over oceans This results in 56 4 billion tonnes C yr 53 8 for terrestrial primary production and 48 5 billion tonnes C yr for oceanic primary production 4 Thus the total photoautotrophic primary production for the Earth is about 104 9 billion tonnes C yr This translates to about 426 gC m2 yr for land production excluding areas with permanent ice cover and 140 gC m2 yr for the oceans However there is a much more significant difference in standing stocks while accounting for almost half of total annual production oceanic autotrophs account for only about 0 2 of the total biomass Terrestrial freshwater ecosystems generate about 1 5 of the global net primary production 53 Some global producers of biomass in order of productivity rates are Producer Biomass productivity gC m2 yr Ref Total area million km2 Ref Total production billion tonnes C yr Swamps and marshes 2 500 2 5 7 54 Tropical rainforests 2 000 55 8 16Coral reefs 2 000 2 0 28 56 0 56Algal beds 2 000 2 River estuaries 1 800 2 Temperate forests 1 250 2 19 24Cultivated lands 650 2 57 17 11Tundras 140 2 57 11 5 29 8 58 59 Open ocean 125 2 57 311 39Deserts 3 57 50 0 15See also editBiomass Biological material from either living see ecology or recently living organisms see bioenergy Biomass energy Biological material used as a renewable energy source Biomass partitioning Organic matter Matter composed of organic compounds Productivity ecology Rate of generation of biomass in an ecosystem Primary nutritional groups Group of organisms Standing stock Measurement of population per unit area or unit volume Slash and burn Stubble burning Lake Pohjalampi body of waterPages displaying wikidata descriptions as a fallback a biomass manipulation study List of commercially important fish species Aquatic animals that are harvested commercially in the greatest amountsReferences edit a b c d e f g h i j k l m n o p q r s t u v w x y Bar On YM Phillips R Milo R June 2018 The biomass distribution on Earth Proceedings of the National Academy of Sciences of the United States of America 115 25 6506 6511 Bibcode 2018PNAS 115 6506B doi 10 1073 pnas 1711842115 PMC 6016768 PMID 29784790 a b c d e f g h i Ricklefs RE Miller GL 2000 Ecology 4th ed Macmillan p 192 ISBN 978 0 7167 2829 0 IUPAC Compendium of Chemical Terminology 2nd ed the Gold Book 1997 Online corrected version 2006 biomass doi 10 1351 goldbook B00660 a b Field CB Behrenfeld MJ Randerson JT Falkowski P July 1998 Primary production of the biosphere integrating 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ecosystem EurekAlert Retrieved 11 December 2018 Dockrill Peter 11 December 2018 Scientists Reveal a Massive Biosphere of Life Hidden Under Earth s Surface Science Alert Retrieved 11 December 2018 Gabbatiss Josh 11 December 2018 Massive deep life study reveals billions of tonnes of microbes living far beneath Earth s surface The Independent Retrieved 11 December 2018 Landenmark HK Forgan DH Cockell CS June 2015 An Estimate of the Total DNA in the Biosphere PLOS Biology 13 6 e1002168 doi 10 1371 journal pbio 1002168 PMC 4466264 PMID 26066900 Nuwer R 18 July 2015 Counting All the DNA on Earth The New York Times New York ISSN 0362 4331 Retrieved 18 July 2015 a b Elhacham Emily Ben Uri Liad et al 2020 Global human made mass exceeds all living biomass Nature 588 7838 442 444 Bibcode 2020Natur 588 442E doi 10 1038 s41586 020 3010 5 PMID 33299177 S2CID 228077506 Spehn Eva M Joshi Jasmin Schmid Bernhard Alphei Jorn Korner Christian 2000 Plant diversity effects on soil heterotrophic activity in 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functional group composition at a global scale Nature 572 8 August 2019 doi 10 1038 s41586 019 1418 6 hdl 10261 193342 Pershing AJ Christensen LB Record NR Sherwood GD Stetson PB August 2010 Humphries S ed The impact of whaling on the ocean carbon cycle why bigger was better PLOS ONE 5 8 e12444 Bibcode 2010PLoSO 512444P doi 10 1371 journal pone 0012444 PMC 2928761 PMID 20865156 Table 1 a b Jelmert A Oppen Berntsen DO 1996 Whaling and Deep Sea Biodiversity Conservation Biology 10 2 653 654 doi 10 1046 j 1523 1739 1996 10020653 x Fisheries NOAA 3 May 2022 Fun Facts About Fascinating Fish NOAA Fisheries NOAA Retrieved 30 July 2023 Johnson Brett M Pate William M Hansen Adam G 2017 Energy Density and Dry Matter Content in Fish New Observations and an Evaluation of Some Empirical Models Transactions of the American Fisheries Society 146 6 1262 1278 doi 10 1080 00028487 2017 1360392 a b c Atkinson A Siegel V Pakhomov EA Jessopp MJ Loeb V 2009 A re appraisal of the total biomass and annual production of Antarctic krill PDF Deep Sea Research Part I 56 5 727 740 Bibcode 2009DSRI 56 727A doi 10 1016 j dsr 2008 12 007 Garcia Pichel F Belnap J Neuer S Schanz F 2003 Estimates of global cyanobacterial biomass and its distribution PDF Algological Studies 109 213 217 doi 10 1127 1864 1318 2003 0109 0213 Alexander DE 1 May 1999 Encyclopedia of Environmental Science Springer ISBN 978 0 412 74050 3 What are wetlands PDF ramsar org Retrieved 28 August 2023 Ricklefs RE Miller GL 2000 Ecology 4th ed Macmillan p 197 ISBN 978 0 7167 2829 0 Mark Spalding Corinna Ravilious and Edmund Green 2001 World Atlas of Coral Reefs Berkeley California University of California Press and UNEP WCMC a b c d Park CC 2001 The environment principles and applications 2nd ed Routledge p 564 ISBN 978 0 415 21770 5 Tundra Biomes WWF World Wildlife Fund Retrieved 5 October 2021 Tundra ArcGIS StoryMaps 17 January 2020 Retrieved 5 October 2021 the tundra is a vast and treeless land which covers about 20 of the Earth s surface circumnavigating the North pole Further reading editFoley JA Monfreda C Ramankutty N Zaks D July 2007 Our share of the planetary pie Proceedings of the National Academy of Sciences of the United States of America 104 31 12585 6 Bibcode 2007PNAS 10412585F doi 10 1073 pnas 0705190104 PMC 1937509 PMID 17646656 Haberl H Erb KH Krausmann F Gaube V Bondeau A Plutzar C Gingrich S Lucht W Fischer Kowalski M July 2007 Quantifying and mapping the human appropriation of net primary production in earth s terrestrial ecosystems Proceedings of the National Academy of Sciences of the United States of America 104 31 12942 7 Bibcode 2007PNAS 10412942H doi 10 1073 pnas 0704243104 PMC 1911196 PMID 17616580 Purves WK Orians GH 2007 Life The Science of Biology 8th ed W H Freeman ISBN 978 1 4292 0877 2 External links edit nbsp Look up biomass in Wiktionary the free dictionary The mass of all life on Earth is staggering until you consider how much we ve lost Counting bacteria Archived 12 December 2013 at the Wayback Machine Trophic levels Biomass distributions for high trophic level fishes in the North Atlantic 1900 2000 Retrieved from https en wikipedia org w index php title Biomass ecology amp oldid 1195821501, wikipedia, wiki, book, books, library,

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