What is the estimated number of extant species?

1. Bar-On, Y. M., Phillips, R., & Milo, R. (2018). The biomass distribution on Earth. Proceedings of the National Academy of Sciences, 201711842. Available at: http://www.pnas.org/content/115/25/6506.

   Table of Contents Show

   • Drivers that affect biodiversity and help animals to resource energy[15]
   • Measuring diversity
   • Known species
   • Estimates of total number of species
   • Importance of biodiversity
   • Biodiversity loss
   • External links

2. To calculate the biomass of a taxonomic group, the researchers multiplied the carbon stock for a single organism by the number of individuals in that group. In humans, for example, they calculate the average carbon quantity of a person and multiply by the human population. If you’re interested in the comparison between biomass and the abundance of different taxonomic groups, you can explore this here.

3. We can calculate our share of total biomass as: 0.06 billion tonnes C (human biomass) / 546 billion tonnes (total biomass) * 100 = 0.01%.

4. Figures for livestock don’t include fish catch or farming — of course, these also had significant impacts on marine life.

5. Poultry livestock on its own accounts for 0.2 percent of animal biomass — more than twice that of wild birds. Bar-On et al. (2018) estimate global poultry biomass to be 0.005 billion tonnes of carbon. This is approximately 0.2 percent of animal biomass (= 0.005 / 2.4 * 100). Wild birds account for only 0.08 percent of animal biomass.

6. Bar-On, Y. M., Phillips, R., & Milo, R. (2018). The biomass distribution on Earth. Proceedings of the National Academy of Sciences, 201711842. Available at: http://www.pnas.org/content/115/25/6506.

7. Parnell, J., & McMahon, S. (2016). Physical and chemical controls on habitats for life in the deep subsurface beneath continents and ice. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 374(2059), 20140293.

8. Total plant biomass is 450 billion tonnes of carbon, so in a maximum case: (1 billion tonnes / 450 billion tonnes) * 100 = 0.02 percent.

9. Pando (a tree), also known as the ‘Trembling Giant’ is a colony of aspen in Utah and named the world’s largest organism. It is determined to be a single living organism based on identical genetic markers and a single underground root system.

10. Suttle, C. A. (2005). Viruses in the sea. Nature, 437(7057), 356-361.

11. Curtis, T. P., & Sloan, W. T. (2005). Exploring microbial diversity–A vast below. Science, 309(5739), 1331-1333.

12. Costello, M. J., May, R. M., & Stork, N. E. (2013). Can we name Earth’s species before they go extinct?. Science, 339(6118), 413-416.

13. Solow, A. R., Mound, L. A., & Gaston, K. J. (1995). Estimating the rate of synonymy. Systematic Biology, 44(1), 93-96.

14. Costello, M. J., May, R. M., & Stork, N. E. (2013). Can we name Earth’s species before they go extinct?. Science, 339(6118), 413-416.

15. May, R. M. (2010). Tropical arthropod species, more or less?. Science, 329(5987), 41-42.

16. Mora, C., Tittensor, D. P., Adl, S., Simpson, A. G., & Worm, B. (2011). How many species are there on Earth and in the ocean?. PLoS Biol, 9(8), e1001127.

17. Costello, M. J., May, R. M., & Stork, N. E. (2013). Can we name Earth’s species before they go extinct?. Science, 339(6118), 413-416.

    A. D. Chapman, Numbers of Living Species in Australia and the World (Biodiversity Information Services, Toowoomba, Australia, 2009).

    Scheffers, B. R., Joppa, L. N., Pimm, S. L., & Laurance, W. F. (2012). What we know and don’t know about Earth’s missing biodiversity. Trends in ecology & evolution, 27(9), 501-510.

18. Mora, C., Tittensor, D. P., Adl, S., Simpson, A. G., & Worm, B. (2011). How many species are there on Earth and in the ocean?. PLoS Biol, 9(8), e1001127.

19. Lewis, S. L., Edwards, D. P., & Galbraith, D. (2015). Increasing human dominance of tropical forests. Science, 349(6250), 827-832.

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@article{owidbiodiversity, author = {Hannah Ritchie and Max Roser}, title = {Biodiversity}, journal = {Our World in Data}, year = {2021}, note = {https://ourworldindata.org/biodiversity} }

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A photo of a young but dead Javan Rhinoceros in Ujung Kulon, Indonesia. Once the most widespread of Asian rhinoceroses, the Javan Rhinoceros ranged from the islands of Indonesia, throughout Southeast Asia, and into India and China. The species is now critically endangered, with only two known populations in the wild, and none in zoos. It is possibly the rarest large mammal on earth.

Total variability of Earth's life forms

This article needs to be updated. Please help update this article to reflect recent events or newly available information. (March 2022)

Global biodiversity is the measure of biodiversity on planet Earth and is defined as the total variability of life forms. More than 99 percent of all species[1] that ever lived on Earth are estimated to be extinct.[2][3] Estimates on the number of Earth's current species range from 2 million to 1 trillion,[4] of which about 1.74 million have been databased thus far[5] and over 80 percent have not yet been described.[6] More recently, in May 2016, scientists reported that 1 trillion species are estimated to be on Earth currently with only one-thousandth of one percent described.[7] The total amount of DNA base pairs on Earth, as a possible approximation of global biodiversity, is estimated at 5.0 x 1037, and weighs 50 billion tonnes.[8] In comparison, the total mass of the biosphere has been estimated to be as much as 4 TtC (trillion tons of carbon).[9]

In other related studies, around 1.9 million extinct species are believed to have been described currently,[10] but some scientists believe 20% are synonyms, reducing the total valid described species to 1.5 million. In 2013, a study published in Science estimated there to be 5 ± 3 million extant species on Earth.[11] Another study, published in 2011 by PLoS Biology, estimated there to be 8.7 million ± 1.3 million eukaryotic species on Earth.[12] Some 250,000 valid fossil species have been described, but this is believed to be a small proportion of all species that have ever lived.[13]

Global biodiversity is affected by extinction and speciation. The background extinction rate varies among taxa but it is estimated that there is approximately one extinction per million species years. Mammal species, for example, typically persist for 1 million years. Biodiversity has grown and shrunk in earth's past due to (presumably) abiotic factors such as extinction events caused by geologically rapid changes in climate. Climate change 299 million years ago was one such event. A cooling and drying resulted in catastrophic rainforest collapse and subsequently a great loss of diversity, especially of amphibians.[14]

Drivers that affect biodiversity and help animals to resource energy[15]

Habitat change (see: habitat fragmentation or habitat destruction) is the most important driver currently affecting biodiversity, as some 40% of forests and ice-free habitats have been converted to cropland or pasture.[16] Other drivers are: overexploitation, pollution, invasive species, and climate change.it helps animals to have energy

Measuring diversity

Biodiversity is usually plotted as the richness of a geographic area, with some reference to a temporal scale. Types of biodiversity include taxonomic or species, ecological, morphological, and genetic diversity. Taxonomic diversity, that is the number of species, genera, family is the most commonly assessed type.[17] A few studies have attempted to quantitatively clarify the relationship between different types of diversity. For example, the biologist Sarda Sahney has found a close link between vertebrate taxonomic and ecological diversity.[18]

Known species

Chapman, 2005 and 2009[10] has attempted to compile perhaps the most comprehensive recent statistics on numbers of extant species, drawing on a range of published and unpublished sources, and has come up with a figure of approximately 1.9 million estimated described taxa, as against possibly a total of between 11 and 12 million anticipated species overall (described plus undescribed), though other reported values for the latter vary widely. It is important to note that in many cases, the values given for "Described" species are an estimate only (sometimes a mean of reported figures in the literature) since for many of the larger groups in particular, comprehensive lists of valid species names do not currently exist. For fossil species, exact or even approximate numbers are harder to find; Raup, 1986[20] includes data based on a compilation of 250,000 fossil species so the true number is undoubtedly somewhat higher than this. It should also be noted that the number of described species is increasing by around 18,000–19,000 extant, and approaching 2,000 fossil species each year, as of 2012.[21][22][23] The number of published species names is higher than the number of described species, sometimes considerably so, on account of the publication, through time, of multiple names (synonyms) for the same accepted taxon in many cases.

Based on Chapman's (2009) report,[10] the estimated numbers of described extant species as of 2009 can be broken down as follows:

Estimates of total number of species

However the total number of species for some taxa may be much higher.

• 10–30 million insects;[24]
• 5–10 million bacteria;[25]
• 1.5 million fungi;[26]
• ~1 million mites[27]
• ~1 million protists[28][29]

In 1982, Terry Erwin published an estimate of global species richness of 30 million, by extrapolating from the numbers of beetles found in a species of tropical tree. In one species of tree, Erwin identified 1200 beetle species, of which he estimated 163 were found only in that type of tree.[30] Given the 50,000 described tropical tree species, Erwin suggested that there are almost 10 million beetle species in the tropics.[31] In 2011 a study published in PLoS Biology estimated there to be 8.7 million ± 1.3 million eukaryotic species on Earth.[12] A 2016 study concludes that Earth is home to 1 trillion species.[32][33]

Indices

After the Convention on Biological Diversity was signed in 1992, biological conservation became a priority for the international community. There are several indicators used that describe trends in global biodiversity. However, there is no single indicator for all extant species as not all have been described and measured over time. There are different ways to measure changes in biodiversity. The Living Planet Index (LPI) is a population-based indicator that combines data from individual populations of many vertebrate species to create a single index.[34] The Global LPI for 2012 decreased by 28%. There are also indices that separate temperate and tropical species for marine and terrestrial species. The Red List Index is based on the IUCN Red List of Threatened Species and measures changes in conservation status over time and currently includes taxa that have been completely categorized: mammals, birds, amphibians and corals.[35] The Global Wild Bird Index is another indicator that shows trends in population of wild bird groups on a regional scale from data collected in formal surveys.[36] Challenges to these indices due to data availability are taxonomic gaps and the length of time of each index.

The Biodiversity Indicators Partnership was established in 2006 to assist biodiversity indicator development, advancement and to increase the availability of indicators.

Importance of biodiversity

Biodiversity is important for humans through ecosystem services and goods. Ecosystem services are broken down into: regulating services such as air and water purification, provisioning services (goods), such as fuel and food, cultural services and supporting services such as pollination and nutrient cycling.[37]

Biodiversity loss

This section is an excerpt from Biodiversity loss.[edit]

Biodiversity loss includes the worldwide extinction of different species, as well as the local reduction or loss of species in a certain habitat, resulting in a loss of biological diversity. The latter phenomenon can be temporary or permanent, depending on whether the environmental degradation that leads to the loss is reversible through ecological restoration/ecological resilience or effectively permanent (e.g. through land loss). The current global extinction (frequently called the sixth mass extinction or Anthropocene extinction), has resulted in a biodiversity crisis being driven by human activities which push beyond the planetary boundaries and so far has proven irreversible.[38][39][40]

Even though permanent global species loss is a more dramatic and tragic phenomenon than regional changes in species composition, even minor changes from a healthy stable state can have dramatic influence on the food web and the food chain insofar as reductions in only one species can adversely affect the entire chain (coextinction), leading to an overall reduction in biodiversity, possible alternative stable states of an ecosystem notwithstanding. Ecological effects of biodiversity are usually counteracted by its loss. Reduced biodiversity in particular leads to reduced ecosystem services and eventually poses an immediate danger for food security, but also can have more lasting public health consequences for humans.[41]

See also

• 
  Ecology portal
• 
  Environment portal
• 
  World portal

• 2010 Biodiversity Indicators Partnership
• Conservation
• Extinction event
• Global Species Database

References

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3. ^ Novacek, Michael J. (8 November 2014). "Prehistory's Brilliant Future". The New York Times. New York. ISSN 0362-4331. Retrieved 2014-12-25.
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External links

• Biodiversity A-Z Archived 2020-09-19 at the Wayback Machine
• Wikispecies
• Biodiversity—Global issues

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