Biomass (ecology)
Biomass is the
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
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
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 turn-overin 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
Terrestrial biomass generally decreases markedly at each higher
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
marine food chain (typical) |
---|
Sun |
↓ |
phytoplankton |
↓ |
herbivorous zooplankton |
↓ |
carnivorous zooplankton |
↓ |
filter feeder |
↓ |
predatory vertebrate |
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
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
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
Among the phytoplankton at the base of the
Bacterial biomass
Bacteria and archaea are both classified as prokaryotes, and their biomass is commonly estimated together. The global biomass of prokaryotes is estimated at 30 billion tonnes C,[20] dominated by bacteria.[1]
Geographic location | Number of cells (× 1029) | Billion tonnes of carbon |
---|---|---|
Open ocean
|
||
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
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
Global biomass
External image | |
---|---|
Visualizing the biomass of life |
The total global biomass has been estimated at 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 |
---|---|---|---|---|
450[1]
|
900
|
2700
|
||
60
|
200
|
|||
12[1]
|
24
|
80
|
||
4[1]
|
8
|
25
|
||
2[1]
|
4
|
13
|
||
Total
|
500
|
1000
|
3000
|
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]
| |||||
1
|
2021
|
1.5 billion[37]
|
300 kg
|
30%
|
125
|
416[27]
| ||
1
|
2021
|
1.3 billion[37]
|
30 kg
|
30%
|
12
|
39[27]
| ||
1
|
2021
|
1.1 billion[37]
|
30 kg
|
30%
|
10
|
32[27]
| ||
1
|
2021
|
26 billion
|
0.9 kg for broilers, 1.8 kg for layers[38]
|
30%
|
8[1]
|
25
| ||
15,700[39]
|
2022
|
22.8%[40]
|
10–100[39]
|
40–450
| ||||
7,000–30,000[41]
|
2016
|
10 mg (dry weight)[42]
|
10–25%[43]
|
400[1]
|
1,600
| |||
2,972[citation needed]
|
2022
|
2 mg[40]
|
27%[40]
|
440[45]
| ||||
2019
|
4.4×1020[46]
|
20%[40]
|
60
|
300[46]
| ||||
Marine
|
1
|
Pre-whaling
|
340,000
|
40%[48]
|
36
| |||
2023
|
50,000[27]
|
60,000 kg
|
40%[48]
|
1.2
|
3[27]
| |||
>20,000[49]
|
2022
|
30%[50]
|
3,000
|
9,000[26]
| ||||
1
|
2008
|
0.486 g[51]
|
379 (in peak season)[51]
| |||||
13,000
|
10−6–10−9 kg
|
|||||||
?
|
2003
|
1,000[52]
|
Global rate of production
Net
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
- Biomass – 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 water - a biomass manipulation study
- List of commercially important fish species – Aquatic animals that are harvested commercially in the greatest amounts
References
- ^ PMID 29784790.
- ^ ISBN 978-0-7167-2829-0.
- ^ PMID 9657713.
- ^ PMID 9618454.
- ^ PMID 22927371.
- ^ 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.
- PMID 26066900.
- ISSN 0362-4331. Retrieved 18 July 2015.
- ^ S2CID 228077506.
- S2CID 25639544.
- JSTOR 3547655.
- PMID 32170296.
- PMID 18159947.
- ^ Nemiroff, R.; Bonnell, J., eds. (27 September 2006). "Earth from Saturn". Astronomy Picture of the Day. NASA.
- PMID 10066832.
- ^ "The Most Important Microbe You've Never Heard Of". npr.org.
- ^ S2CID 133768246.
- ^ Observatory, Deep Carbon. "Life in deep Earth totals 15 to 23 billion tons of carbon—hundreds of times more than humans". phys.org. Retrieved 24 July 2023.
- ^ S2CID 67789580.
- ISSN 0948-3055.
- ^ a b Groombridge B, Jenkins MD (2000) Global biodiversity: Earth's living resources in the 21st century Page 11. World Conservation Monitoring Centre, World Conservation Press, Cambridge
- S2CID 233678539.
- ^ PMID 34757796.
- ^ PMID 36848563.
- ^ PMID 36735788.
- ^ Gosh, Iman (20 August 2021). "Misc All the Biomass of Earth, in One Graphic". Visual Capitalist. Retrieved 16 December 2021.
- ^ a b Hartley, Sue (2010) The 300 Million Years War: Plant Biomass v Herbivores Royal Institution Christmas Lecture.
- ^ Laville, Sandra (9 December 2020). "Human-made materials now outweigh Earth's entire biomass – study". The Guardian. Retrieved 9 December 2020.
- ^ "Anthropogenic mass: Comparing human-made mass to the living Biomass on earth". Anthropogenic mass: Comparing human-made mass to the living Biomass on earth. Retrieved 31 July 2023.
- ^ Nations, United. "Day of 8 Billion". United Nations. Retrieved 9 July 2023.
- S2CID 86671730– via JSTOR.
- S2CID 205129670.
- ^ PMID 22709383.
- ^ a b c "FAOSTAT". www.fao.org. Retrieved 26 July 2023.
- ^ IPCC 2006, 2006 IPCC Guidelines for National Greenhouse Gas Inventories, Prepared by the National Greenhouse Gas Inventories Programme, Eggleston H.S., Buendia L., Miwa K., Ngara T. and Tanabe K. (eds). Published: IGES, Japan.
- ^ PMID 36122199.
- ^ JSTOR 3544689. Retrieved 26 July 2023.
- ISBN 978-92-79-48168-0.
- PMID 19674041.
- ISBN 978-0-387-74943-3.
- S2CID 209482348.
- ^ Sum of [(biomass m−22)*(area m2)] from table 3 in Sanderson, M.G. 1996 Biomass of termites and their emissions of methane and carbon dioxide: A global database Global Biochemical Cycles, Vol 10:4 543-557
- ^ PMID 31341281.
- PMID 20865156. (Table 1)
- ^ .
- ^ Fisheries, NOAA (3 May 2022). "Fun Facts About Fascinating Fish | NOAA Fisheries". NOAA. Retrieved 30 July 2023.
- .
- ^ .
- .
- ISBN 978-0-412-74050-3.
- ^ "What are wetlands?" (PDF). ramsar.org. Retrieved 28 August 2023.
- 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.
- ^ 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
- 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. PMID 17646656.
- Haberl H, Erb KH, Krausmann F, Gaube V, Bondeau A, Plutzar C, Gingrich S, Lucht W, 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
- Biocubes: a visualization of biomass and technomass
- 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