Scorpion#Medical use

The word scorpion originated in Middle English between 1175 and 1225 AD from Old French {{lang|fro|scorpion}},{{cite web |title=Scorpion |website=The American Heritage Dictionary of the English Language, 5th Edition |date=2016 |access-date=7 December 2020 |url=https://www.thefreedictionary.com/scorpion |archive-date=22 November 2020 |archive-url=https://web.archive.org/web/20201122213551/https://www.thefreedictionary.com/scorpion |url-status=live }} or from Italian {{Lang|it|scorpione}}, both derived from the Latin {{Lang|la|scorpio}}, equivalent to {{Lang|la|scorpius}},{{cite web |title=Scorpion |website=Dictionary.com |url=http://dictionary.reference.com/browse/scorpion |access-date=7 December 2020 |archive-date=15 November 2015 |archive-url=https://web.archive.org/web/20151115230956/http://dictionary.reference.com/browse/scorpion |url-status=live }} which is the romanization of the Greek {{lang|el|σκορπίος}} – {{lang|el|skorpíos}},{{LSJ|skorpi/os|σκορπίος|ref}}. with no native IE etymology (cfr. Arabic ʕaqrab 'scorpion', Proto-Germanic *krabbô 'crab').

File:Palaeophonus nuncius NRM PAL Ar0032235.jpg, a Silurian scorpion from Sweden]]

Scorpion fossils have been found in many strata, including marine Silurian and estuarine Devonian deposits, coal deposits from the Carboniferous Period and in amber. Whether the early scorpions were marine or terrestrial has been debated, and while they had book lungs like modern terrestrial species,{{cite journal |last1=Scholtz |first1=Gerhard |last2=Kamenz |first2=Carsten |title=The Book Lungs of Scorpiones and Tetrapulmonata (Chelicerata, Arachnida): Evidence for Homology and a Single Terrestrialisation Event of a Common Arachnid Ancestor |year=2006 |journal=Zoology |volume=109 |issue=1 |pages=2–13 |pmid=16386884 |doi=10.1016/j.zool.2005.06.003 |bibcode=2006Zool..109....2S }}{{cite journal |last1=Dunlop |first1=Jason A. |last2=Tetlie |first2=O. Erik |last3=Prendini |first3=Lorenzo |doi=10.1111/j.1475-4983.2007.00749.x |title=Reinterpretation of the Silurian Scorpion Proscorpius osborni (Whitfield): Integrating Data from Palaeozoic and Recent Scorpions |year=2008 |journal=Palaeontology |volume=51 |issue=2 |pages=303–320|bibcode=2008Palgy..51..303D |doi-access=free }}{{cite journal |last1=Kühl |first1=G. |first2=A. |last2=Bergmann |first3=J. |last3=Dunlop |first4=R. J. |last4=Garwood |first5=J. |last5=Rust |doi=10.1111/j.1475-4983.2012.01152.x |title=Redescription and Palaeobiology of Palaeoscorpius devonicus Lehmann, 1944 from the Lower Devonian Hunsrück Slate of Germany |year=2012 |journal=Palaeontology |volume=55 |issue=4 |pages=775–787|bibcode=2012Palgy..55..775K |doi-access=free }} the most basal such as Eramoscorpius were originally considered as still aquatic,{{cite journal |last1=Waddington |first1=Janet |last2=Rudkin |first2=David M. |last3=Dunlop |first3=Jason A. |title=A new mid-Silurian aquatic scorpion—one step closer to land? |journal=Biology Letters |date=January 2015 |volume=11 |issue=1 |pages=20140815 |doi=10.1098/rsbl.2014.0815|pmid=25589484 |pmc=4321148 }} until it was found that Eramoscorpius had book lungs.{{Cite journal |last1=Haug |first1=C. |last2=Wagner |first2=P. |last3=Haug |first3=J.T. |date=2019-12-31 |title=The evolutionary history of body organisation in the lineage towards modern scorpions |journal=Bulletin of Geosciences |pages=389–408 |doi=10.3140/bull.geosci.1750 |issn=1802-8225 |doi-access=free}} Over 100 fossil species of scorpion have been described.{{cite book |last1=Dunlop |first1=J. A. |last2=Penney |first2=D. |year=2012 |title=Fossil Arachnids |publisher=Siri Scientific Press |page=23 |isbn=978-0956779540}} The oldest found as of 2021 is Dolichophonus loudonensis, which lived during the Silurian, in present-day Scotland.{{Cite journal|last1=Anderson|first1=Evan P.|last2=Schiffbauer|first2=James D.|last3=Jacquet|first3=Sarah M.|last4=Lamsdell|first4=James C.|last5=Kluessendorf|first5=Joanne|last6=Mikulic|first6=Donald G.|date=2021|title=Stranger than a scorpion: a reassessment of Parioscorpio venator, a problematic arthropod from the Llandoverian Waukesha Lagerstätte|url=https://onlinelibrary.wiley.com/doi/abs/10.1111/pala.12534|journal=Palaeontology|language=en|volume=64|issue=3|pages=429–474|doi=10.1111/pala.12534|bibcode=2021Palgy..64..429A |s2cid=234812878|issn=1475-4983|access-date=20 April 2021|archive-date=20 April 2021|archive-url=https://web.archive.org/web/20210420145034/https://onlinelibrary.wiley.com/doi/abs/10.1111/pala.12534|url-status=live|url-access=subscription}} Gondwanascorpio from the Devonian is among the earliest-known terrestrial animals on the Gondwana supercontinent.{{cite journal |last=Gess |first=R. W. |year=2013 |title=The Earliest Record of Terrestrial Animals in Gondwana: a Scorpion from the Famennian (Late Devonian) Witpoort Formation of South Africa |journal=African Invertebrates |volume=54 |issue=2 |pages=373–379 |doi=10.5733/afin.054.0206 |doi-access=free |bibcode=2013AfrIn..54..373G }} Some Palaeozoic scorpions possessed compound eyes similar to those of eurypterids.{{cite journal | pmid=31780700 | year=2019 | last1=Schoenemann | first1=B. | last2=Poschmann | first2=M. | author3=Clarkson ENK | title=Insights into the 400 million-year-old eyes of giant sea scorpions (Eurypterida) suggest the structure of Palaeozoic compound eyes | journal=Scientific Reports | volume=9 | issue=1 | page=17797 | doi=10.1038/s41598-019-53590-8 | pmc=6882788 | bibcode=2019NatSR...917797S }} The Triassic fossils Protochactas and Protobuthus belong to the modern clades Chactoidea and Buthoidea respectively, indicating that the crown group of modern scorpions had emerged by this time.{{Cite journal |last1=Magnani, Fabio |last2=Stockar, Rudolf |last3=Lourenço, Wilson R. |date=2022 |others=Lionel Delaunay |title=Une nouvelle famille, genre et espèce de scorpion fossile du Calcaire de Meride (Trias Moyen) du Mont San Giorgio (Suisse)A new family, genus and species of fossil scorpion from the Meride Limestone (Middle Triassic) of Monte San Giorgio (Switzerland) |journal=Faunitaxys |volume=10 |issue=24 |url=https://hal.archives-ouvertes.fr/hal-03660445v1 |language=en |pages=1–7 |doi=10.57800/FAUNITAXYS-10(24)}}

In July 2025, it was reported that a 140 million year old scorpion was dicovered in a Jordanian amber by Scientist Abbas Haddadin.{{Cite web |last1=Jul 08 |first1=last updated |last2=2025 |date=2025-07-08 |title=A 140-Million-Year-Old Scorpion was discovered in Jordanian Amber - Jordan News {{!}} Latest News from Jordan, MENA |url=https://www.jordannews.jo/Section-114/All/A-140-Million-Year-Old-Scorpion-was-discovered-in-Jordanian-Amber-43056 |access-date=2025-07-13 |website=Jordan News {{!}} Latest News from Jordan, MENA |language=en}}

The Scorpiones are a clade within the pulmonate Arachnida (those with book lungs). Arachnida is placed within the Chelicerata, a subphylum of Arthropoda that contains sea spiders and horseshoe crabs, alongside terrestrial animals without book lungs such as ticks and harvestmen. The extinct Eurypterida, sometimes called sea scorpions, though they were not all marine, are not scorpions; their grasping pincers were chelicerae, unlike those of scorpion which are second appendages.{{cite web |last=Waggoner |first=B. M. |title=Eurypterida: Morphology |url=https://ucmp.berkeley.edu/arthropoda/chelicerata/eurypteridmm.html |publisher=University of California Museum of Paleontology Berkeley |access-date=20 October 2020 |date=12 October 1999 |archive-date=23 October 2020 |archive-url=https://web.archive.org/web/20201023013411/https://ucmp.berkeley.edu/arthropoda/chelicerata/eurypteridmm.html |url-status=live }} Scorpiones is sister to the Tetrapulmonata, a terrestrial group of pulmonates containing the spiders and whip scorpions.

Recent studies place pseudoscorpions as the sister group of scorpions in the clade Panscorpiones, which together with Tetrapulmonata makes up the clade Arachnopulmonata.{{cite journal |first1=Andrew Z.|last1=Ontano|first2=Guilherme|last2=Gainett |first3=Shlomi|last3=Aharon |first4=Jesús A.|last4=Ballesteros |first5=Ligia R.|last5=Benavides |first6=Kevin F.|last6=Corbett |first7=Efrat|last7=Gavish-Regev|first8=Mark S.|last8=Harvey|first9=Scott|last9=Monsma|first10=Carlos E.|last10=Santibáñez-López |first11=Emily V. W.|last11=Setton|first12=Jakob T.|last12=Zehms|first13=Jeanne A.|last13=Zeh|first14=David W. |last14=Zeh |first15=Prashant P. |last15=Sharma |display-authors=5 |url=https://www.biorxiv.org/content/10.1101/2020.11.18.389098v1 |title=Taxonomic sampling and rare genomic changes overcome long-branch attraction in the phylogenetic placement of pseudoscorpions |journal=Molecular Biology and Evolution |volume=38 |issue=6 |date=June 2021 |pages=2446–2467 |doi=10.1093/molbev/msab038 |pmid=33565584 |pmc=8136511 }}

Cladogram of current understanding of chelicerate relationships, after Sharma and Gavish-Regev (2025):{{Cite journal |last1=Sharma |first1=Prashant P. |last2=Gavish-Regev |first2=Efrat |date=2025-01-28 |title=The Evolutionary Biology of Chelicerata |journal=Annual Review of Entomology |volume=70 |issue=1 |pages=143–163 |doi=10.1146/annurev-ento-022024-011250 |issn=0066-4170 |doi-access=free|pmid=39259983 }}

{{clade|{{clade

|1=Pycnogonida (sea spiders) 70px

|label2=Prosomapoda

|2={{clade

|1=Opiliones (harvestmen) 70px

|state2=dashed

|2={{clade

|state1=dashed

|1=Palpigradi (microwhip scorpions) 70px

|state2=dashed

|2={{clade

|state1=dashed

|1=Solifugae (camel spiders) 70px

|state2=dashed

|2=Acariformes (mites, in part) 70px

}}

}}

|3=Parasitiformes (mites, in part and ticks) 70px

|4={{clade

|state1=dashed

|1=Xiphosura (horseshoe crabs) 70px

|state2=dashed

|2=Ricinulei 70px

|label3=Arachnopulmonata

|3={{clade

|label1=Panscorpiones

|1={{clade

|1=Pseudoscorpiones (pseudoscorpions) 70px

|2=Scorpiones (scorpions) 70px

}}

|label2=Tetrapulmonata

|2={{clade

|1=Araneae (spiders) 60px

|2={{clade

|1=Amblypygi (whip-spiders) 70px

|2={{clade

|1=Schizomida (shorttailed whipscorpions) 70px

|2=Uropygi (whip scorpions/vinegaroons) 70px

}}

}}

}}

}}

}}

}}

}}

|label1=Chelicerata}}

The internal phylogeny of the scorpions has been debated,{{cite journal |last1=Howard |first1=Richard J. |last2=Edgecombe |first2=Gregory D. |last3=Legg |first3=David A. |last4=Pisani |first4=Davide |last5=Lozano-Fernandez |first5=Jesus |title=Exploring the Evolution and Terrestrialization of Scorpions (Arachnida: Scorpiones) with Rocks and Clocks |journal=Organisms Diversity & Evolution |volume=19 |issue=1 |year=2019 |pages=71–86 |issn=1439-6092 |doi=10.1007/s13127-019-00390-7 |doi-access=free|bibcode=2019ODivE..19...71H |hdl=10261/217081 |hdl-access=free }} but genomic analysis consistently places the Bothriuridae as sister to a clade consisting of Scorpionoidea and Chactoidea. The scorpions diversified during the Devonian and into the early Carboniferous. The main division is into the clades Buthida and Iurida. The Bothriuridae diverged starting before temperate Gondwana broke up into separate land masses, completed by the Jurassic. The Iuroidea and Chactoidea are both seen not to be single clades, and are shown as "paraphyletic" (with quotation marks) in this 2018 cladogram.{{cite journal |last1=Sharma |first1=Prashant P. |last2=Baker |first2=Caitlin M. |last3=Cosgrove |first3=Julia G. |last4=Johnson |first4=Joanne E. |last5=Oberski |first5=Jill T. |last6=Raven |first6=Robert J. |last7=Harvey |first7=Mark S. |last8=Boyer |first8=Sarah L. |last9=Giribet |first9=Gonzalo |title=A Revised Dated Phylogeny of Scorpions: Phylogenomic Support for Ancient Divergence of the Temperate Gondwanan Family Bothriuridae |journal=Molecular Phylogenetics and Evolution |volume=122 |year=2018 |pages=37–45 |issn=1055-7903 |doi=10.1016/j.ympev.2018.01.003 |pmid=29366829 |doi-access=free |bibcode=2018MolPE.122...37S }}

{{clade

|label1=Scorpiones

|1={{clade

|label1=Buthida

|1={{clade

|1={{clade

|1=Chaeriloidea 55px

|2=Pseudochactoidea 45px

}}

|2=Buthoidea 65px

}}

|label2=Iurida

|2={{clade

|1="Iuroidea" (part)

|2={{clade

|1=Bothriuroidea 80px

|2={{clade

|1={{clade

|1={{clade

|1="Chactoidea" (part)

|2="Iuroidea" (part)

}}

|2="Chactoidea" (part)

}}

|2=Scorpionoidea 75px

}}

}}

}}

}}

}}

{{main|Taxonomy of scorpions}}

Carl Linnaeus described six species of scorpion in his genus Scorpio in 1758 and 1767; three of these are now considered valid and are called Scorpio maurus, Androctonus australis, and Euscorpius carpathicus; the other three are dubious names. He placed the scorpions among his "Insecta aptera" (wingless insects).{{cite journal |last1=Fet |first1=V. |last2=Braunwalder |first2=M. E. |last3=Cameron |first3=H. D. |title=Scorpions (Arachnida, Scorpiones) Described by Linnaeus |journal=Bulletin of the British Arachnological Society |date=2002 |volume=12 |issue=4 |pages=176–182 |url=http://britishspiders.org.uk/bulletin/120405.pdf |access-date=20 October 2020 |archive-date=26 September 2020 |archive-url=https://web.archive.org/web/20200926182646/http://britishspiders.org.uk/bulletin/120405.pdf |url-status=live }} In 1801, Jean-Baptiste Lamarck divided up the "Insecta aptera", creating the taxon Arachnides for spiders, scorpions, and acari (mites and ticks), though it also contained the Thysanura, Myriapoda and parasites such as lice.{{cite book |last1=Burmeister |first1=Carl Hermann C. |last2=Shuckard |first2=W. E. (trans) |title=A Manual of Entomology |url=https://books.google.com/books?id=g9sDAAAAQAAJ&pg=PA613 |year=1836 |pages=613ff |access-date=20 October 2020 |archive-date=31 May 2021 |archive-url=https://web.archive.org/web/20210531031222/https://books.google.com/books?id=g9sDAAAAQAAJ&pg=PA613 |url-status=live }} German arachnologist Carl Ludwig Koch created the order Scorpiones in 1837. He divided it into four families, the six-eyed scorpions "Scorpionides", the eight-eyed scorpions "Buthides", the ten-eyed scorpions "Centrurides", and the twelve-eyed scorpions "Androctonides".{{cite book |last=Koch |first=Carl Ludwig |title=Übersicht des Arachnidensystems |date=1837 |publisher=C. H. Zeh |pages=86–92 |url=https://archive.org/details/bersichtdesara1518371850koch/page/n91/mode/2up?q=Scorpiones |language=de}}

More recently, some twenty-two families containing over 2,500 species of scorpions have been described, with many additions and much reorganization of taxa in the 21st century.{{cite web |url=http://kovarex.com/scorpio/pdf/scorpions-Kovarik-2009.pdf |first=František |last=Kovařík |year=2009 |title=Illustrated Catalog of Scorpions, Part I |access-date=22 January 2011 |archive-date=26 October 2010 |archive-url=https://web.archive.org/web/20101026163042/http://kovarex.com/scorpio/pdf/scorpions-Kovarik-2009.pdf |url-status=live }} There are over 100 described taxa of fossil scorpions. This classification is based on Soleglad and Fet (2003),{{cite journal |last1=Soleglad |first1=Michael E. |last2=Fet |first2=Victor |year=2003 |title=High-level Systematics and Phylogeny of the Extant Scorpions (Scorpiones: Orthosterni) |journal=Euscorpius |volume=11 |pages=1–175 |url=http://www.science.marshall.edu/fet/euscorpius/pubs.htm |format=multiple parts |access-date=13 June 2008 |archive-date=8 December 2019 |archive-url=https://web.archive.org/web/20191208071547/http://www.science.marshall.edu/fet/euscorpius/pubs.htm |url-status=live }} which replaced Stockwell's older, unpublished classification.{{cite thesis |last=Stockwell |first=Scott A. |title=Revision of the Phylogeny and Higher Classification of Scorpions (Chelicerata) |year=1989 |publisher=University of California, Berkeley|type=PhD thesis}} Further taxonomic changes are from papers by Soleglad et al. (2005).{{cite journal |last1=Soleglad |first1=Michael E. |last2=Fet |first2=Victor |last3=Kovařík |first3=F. |year=2005 |title=The Systematic Position of the Scorpion Genera Heteroscorpion Birula, 1903 and Urodacus Peters, 1861 (Scorpiones: Scorpionoidea) |journal=Euscorpius |volume=20 |pages=1–38 |url=http://www.science.marshall.edu/fet/euscorpius/p2005_20.pdf |access-date=13 June 2008 |archive-date=16 December 2008 |archive-url=https://web.archive.org/web/20081216234048/http://www.science.marshall.edu/fet/euscorpius/p2005_20.pdf |url-status=live }}{{cite journal |last1=Fet |first1=Victor |last2=Soleglad |first2=Michael E. |year=2005 |title=Contributions to Scorpion Systematics. I. On Recent Changes in High-level Taxonomy |journal=Euscorpius |issue=31 |pages=1–13 |url=http://www.science.marshall.edu/fet/euscorpius/p2005_31.pdf |issn=1536-9307 |access-date=7 April 2010 |archive-date=26 April 2018 |archive-url=https://web.archive.org/web/20180426135453/http://www.science.marshall.edu/fet/euscorpius/p2005_31.pdf |url-status=live }}

The extant taxa to the rank of family (numbers of species in parentheses{{cite web |title=The Scorpion Files |url=https://www.ntnu.no/ub/scorpion-files/index.php |publisher=Jan Ove Rein |access-date=15 August 2020 |archive-date=3 October 2020 |archive-url=https://web.archive.org/web/20201003094246/https://www.ntnu.no/ub/scorpion-files/index.php |url-status=live }}) are:

; Order Scorpiones

File:StripedBarkScorpion.jpg, the striped bark scorpion, a member of Buthidae, the largest family of scorpions]]

File:Asian forest scorpion in Khao Yai National Park.JPG, the Vietnam forest scorpion, a member of the family Scorpionidae]]

{{div col begin|colwidth=40em}}

• Parvorder Pseudochactida Soleglad & Fet, 2003

• Superfamily Pseudochactoidea Gromov, 1998
• Family Pseudochactidae Gromov, 1998 (1 sp.) (Central Asian scorpions of semi-savanna habitats)

• Parvorder Buthida Soleglad & Fet, 2003

• Superfamily Buthoidea C. L. Koch, 1837
• Family Buthidae C. L. Koch, 1837 (1209 spp.) (thick-tailed scorpions, including the most dangerous species)
• Family Microcharmidae Lourenço, 1996, 2019 (17 spp.) (African scorpions of humid forest leaf litter)

• Parvorder Chaerilida Soleglad & Fet, 2003

• Superfamily Chaeriloidea Pocock, 1893
• Family Chaerilidae Pocock, 1893 (51 spp.) (South and Southeast Asian scorpions of non-arid places)

• Parvorder Iurida Soleglad & Fet, 2003

• Superfamily Chactoidea Pocock, 1893
• Family Akravidae Levy, 2007 (1 sp.) (cave-dwelling scorpions of Israel)
• Family Belisariidae Lourenço, 1998 (3 spp.) (cave-related scorpions of Southern Europe)
• Family Chactidae Pocock, 1893 (209 spp.) (New World scorpions, membership under revision)
• Family Euscorpiidae Laurie, 1896 (170 spp.) (harmless scorpions of the Americas, Eurasia, and North Africa)
• Family Superstitioniidae Stahnke, 1940 (1 sp.) (cave scorpions of Mexico and Southwestern United States)
• Family Troglotayosicidae Lourenço, 1998 (4 spp.) (cave-related scorpions of South America)
• Family Typhlochactidae Mitchell, 1971 (11 spp.) (cave-related scorpions of Eastern Mexico)
• Family Vaejovidae Thorell, 1876 (222 spp.) (New World scorpions)

• Superfamily Iuroidea Thorell, 1876
• Family Caraboctonidae Kraepelin, 1905 (23 spp.) (hairy scorpions)
• Family Hadruridae Stahnke, 1974 (9 spp.) (large North American scorpions)
• Family Iuridae Thorell, 1876 (21 spp.) (scorpions with a large tooth on inner side of moveable claw)

• Superfamily Scorpionoidea Latreille, 1802
• Family Bothriuridae Simon, 1880 (158 spp.) (Southern hemisphere tropical and temperate scorpions)
• Family Hemiscorpiidae Pocock, 1893 (16 spp.) (rock, creeping, or tree scorpions of the Middle East)
• Family Hormuridae Laurie, 1896 (92 spp.) (flattened, crevice-living scorpions of Southeast Asia and Australia)
• Family Rugodentidae Bastawade et al., 2005 (1 sp.) (burrowing scorpions of India)
• Family Scorpionidae Latreille, 1802 (183 spp.) (burrowing or pale-legged scorpions)
• Family Diplocentridae Karsch, 1880 (134 spp.) (closely related to and sometimes placed in Scorpionidae, but have spine on telson)
• Family Heteroscorpionidae Kraepelin, 1905 (6 spp.) (scorpions of Madagascar)

{{div col end}}

Scorpions are found on all continents except Antarctica. They are usually among animal groups in that they are most diverse at the subtropics rather than the tropics, and are also less common near the poles.{{sfn|Polis|1990|p=249}} New Zealand, and some of the islands in Oceania, have in the past had small populations of introduced scorpions, but they were exterminated.{{Cite web |date=2018-04-06 |title=Critter of the Week The Pseudoscorpion! |url=https://www.rnz.co.nz/national/programmes/afternoons/audio/2018639383/critter-of-the-week-the-pseudoscorpion |access-date=2022-09-05 |website=RNZ |language=en-nz}}{{sfn|Polis|1990|p=249}} Five colonies of Euscorpius flavicaudis have established themselves since the late 19th century in Sheerness in England at 51°N,{{cite journal |first=T. G. |last=Benton |year=1992 |title=The Ecology of the Scorpion Euscorpius flavicaudis in England |journal=Journal of Zoology |volume=226 |issue=3 |pages=351–368 |doi=10.1111/j.1469-7998.1992.tb07484.x}}{{cite journal |last1=Benton |first1=T. G. |title=The Life History of Euscorpius flavicaudis (Scorpiones, Chactidae) |journal=The Journal of Arachnology |date=1991 |volume=19 |issue=2 |pages=105–110 |jstor=3705658 |url=http://www.americanarachnology.org/JoA_free/JoA_v19_n2%20/JoA_v19_p105.pdf |access-date=16 January 2008 |archive-date=28 February 2008 |archive-url=https://web.archive.org/web/20080228194248/http://www.americanarachnology.org/JoA_free/JoA_v19_n2%20/JoA_v19_p105.pdf |url-status=live }}{{cite web |url=https://www.ntnu.no/ub/scorpion-files/e_flavicaudis.php |title=Euscorpius flavicaudis |access-date=13 June 2008 |first=Jan Ove |last=Rein |year=2000 |website=The Scorpion Files |publisher=Norwegian University of Science and Technology |archive-date=26 April 2018 |archive-url=https://web.archive.org/web/20180426135809/https://www.ntnu.no/ub/scorpion-files/e_flavicaudis.php |url-status=live }} while Paruroctonus boreus lives as far north as Red Deer, Alberta.{{cite book |last=Johnson |first=D. L. |url=http://people.uleth.ca/~dan.johnson/scorpions/northern_scorpion_dj.pdf |date=2004 |chapter=The Northern Scorpion, Paruroctonus boreus, in Southern Alberta, 1983–2003 |title=Arthropods of Canadian Grasslands 10 |publisher=Biological Survey of Canada |url-status=dead |archive-url=https://web.archive.org/web/20151129125229/http://people.uleth.ca/~dan.johnson/scorpions/northern_scorpion_dj.pdf |archive-date=29 November 2015}} A few species are on the IUCN Red List; Afrolychas braueri is classed as critically endangered (2012), Isometrus deharvengi as endangered (2016) and Chiromachus ochropus as vulnerable (2014).{{cite iucn |author=Gerlach, J. |year=2022 |errata=2022 |title=Afrolychas braueri |page=e.T21460801A211822304 |doi= |access-date=3 January 2025}}{{cite iucn |author=Deharveng, L. |author2=Bedos, A. |year=2016 |title=Isometrus deharvengi |page=e.T89656504A89656508 |doi=10.2305/IUCN.UK.2016-1.RLTS.T89656504A89656508.en}}{{cite iucn |author=Gerlach, J. |year=2014 |title=Chiromachus ochropus |page=e.T196784A21568706 |doi=10.2305/IUCN.UK.2014-1.RLTS.T196784A21568706.en}}

Scorpions are usually xerocoles, primarily living in deserts, but they can be found in virtually every terrestrial habitat including high-elevation mountains, caves, and intertidal zones. They are largely absent from boreal ecosystems such as the tundra, high-altitude taiga, and mountain tops.{{sfn|Polis|1990|pp=251–253}} The highest altitude reached by a scorpion is {{convert|5500|m|ft|sp=us}} in the Andes, for Orobothriurus crassimanus.{{sfn|Stockmann|Ythier|2010|p=151}} As regards microhabitats, scorpions may be ground-dwelling, tree-loving, rock-loving or sand-loving. Some species, such as Vaejovis janssi, are versatile and use any habitat on Socorro Island, Baja California, while others such as Euscorpius carpathicus, endemic to the littoral zone of rivers in Romania, occupy specialized niches.{{cite web |last=Ramel |first=Gordon |title=The Earthlife Web: The Scorpions |publisher=The Earthlife Web |url=http://www.earthlife.net/chelicerata/scorpionidae.html |access-date=8 April 2010 |archive-date=9 October 2019 |archive-url=https://web.archive.org/web/20191009122613/https://www.earthlife.net/chelicerata/scorpionidae.html |url-status=live }}{{cite journal |last1=Gherghel |first1=I. |last2=Sotek |first2=A. |last3=Papes |first3=M. |last4=Strugariu |first4=A. |last5=Fusu |first5=L. |year=2016 |title=Ecology and Biogeography of the Endemic Scorpion Euscorpius carpathicus (Scorpiones: Euscorpiidae): a Multiscale Analysis |journal=Journal of Arachnology |volume=44 |issue=1 |pages=88–91 |doi=10.1636/P14-22.1 |s2cid=87325752}}

File:Scorpion anatomy.svg):
1 = Cephalothorax or prosoma;
2 = Preabdomen or mesosoma;
3 = Tail or metasoma;
4 = Claws or pedipalps;
5 = Legs;
6 = Mouth parts or chelicerae;
7 = Pincers or chelae;
8 = Moveable claw or tarsus;
9 = Fixed claw or manus;
10 = Stinger or aculeus;
11 = Telson (anus in previous joint);
12 = Opening of book lungs]]

Scorpions range in size from the {{convert|8.5|mm|in|abbr=on|adj=on}} Typhlochactas mitchelli of Typhlochactidae, to the {{convert|23|cm|in|abbr=on|adj=on}} Heterometrus swammerdami of Scorpionidae.{{cite book |first=Manny |last=Rubio |year=2000 |title=Scorpions: Everything About Purchase, Care, Feeding, and Housing |publisher=Barron's |isbn=978-0-7641-1224-9 |chapter=Commonly Available Scorpions |pages=26–27 |chapter-url=https://archive.org/details/scorpionscomplet00mann/page/26 |quote=The Guinness Book of Records claims [...] Heterometrus swammerdami, to be the largest scorpion in the world [9 inches (23 cm)]}} The body of a scorpion is divided into two parts or tagmata: the cephalothorax or prosoma, and the abdomen or opisthosoma.{{efn|As there is currently neither paleontological nor embryological evidence that arachnids ever had a separate thorax-like division, there exists an argument against the validity of the term cephalothorax, which means fused cephalon (head) and the thorax. Similarly, arguments can be formed against use of the term abdomen, as the opisthosoma of all scorpions contains a heart and book lungs, organs atypical of an abdomen.{{cite book |last1=Shultz |first1=Stanley |last2=Shultz |first2=Marguerite |title=The Tarantula Keeper's Guide |date=2009 |publisher=Barron's |isbn=978-0-7641-3885-0 |page=23}}}} The opisthosoma consists of a broad anterior portion, the mesosoma or pre-abdomen, followed by a thinner tail-like posterior, the metasoma or post-abdomen.{{sfn|Polis|1990|pp=10–11}} External differences between the sexes are not obvious in most species. In some, the tail of the male is slenderer than that of the female.{{sfn|Stockmann|Ythier|2010|p=76}}

The cephalothorax comprises the carapace, eyes, chelicerae (mouth parts), pedipalps (which have chelae, commonly called claws or pincers) and four pairs of walking legs. Scorpions have two eyes on the top of the cephalothorax, and usually two to five pairs of eyes along the front corners of the cephalothorax. While unable to form sharp images, their central eyes are amongst the most light sensitive in the animal kingdom, especially in dim light, which makes it possible for nocturnal species to use starlight to navigate at night.{{cite book |last1=Chakravarthy |first1=Akshay Kumar |last2=Sridhara |first2=Shakunthala |title=Arthropod Diversity and Conservation in the Tropics and Sub-tropics |url=https://books.google.com/books?id=wLiVDQAAQBAJ&pg=PA60 |year=2016 |publisher=Springer |isbn=978-981-10-1518-2 |page=60 |access-date=11 September 2017 |archive-date=31 May 2021 |archive-url=https://web.archive.org/web/20210531031224/https://books.google.com/books?id=wLiVDQAAQBAJ&pg=PA60 |url-status=live }} The chelicerae are at the front and below the carapace. They are pincer-like and have three segments and "teeth".{{sfn|Polis|1990|pp=16–17}}{{sfn|Stockmann|2015|p=26}} The brain of a scorpion is located in the front part of the cephalothorax, just above the esophagus.{{sfn|Polis|1990|p=38}} As in other arachnids, the nervous system is highly concentrated in the cephalothorax, but has a long ventral nerve cord with segmented ganglia which may be a primitive trait.{{sfn|Polis|1990|p=342}}

The pedipalp is a segmented, clawed appendage segmented into (from closest to the body outward) the coxa, trochanter, femur, patella, tibia (including the fixed claw and the manus) and tarsus (moveable claw).{{sfn|Polis|1990|p=12}} Unlike those of some other arachnids, the eight-segmented legs have not been altered for other purposes, though they may occasionally be used for digging, and females may use them to catch emerging young. They are covered with many proprioceptors, bristles and sensory setae.{{sfn|Polis|1990|p=20}} Depending on the species, the legs may have spines and spurs.{{sfn|Polis|1990|p=74}}

File:Vista ventral de un escorpión.jpg have a comblike structure in an inverted V shape.]]

The mesosoma or preabdomen is the broad part of the opisthosoma.{{sfn|Polis|1990|pp=10–11}} In the early stages of embryonic development the mesosoma consist of eight segments, but the first segment disappear before birth, so the mesosoma in scorpions actually consist of segments 2-8.{{Cite journal|title=The ultrastructure of book lung development in the bark scorpion Centruroides gracilis (Scorpiones: Buthidae) - PMC|year=2011 |pmc=3199777 |last1=Farley |first1=R. D. |journal=Frontiers in Zoology |volume=8 |page=18 |doi=10.1186/1742-9994-8-18 |pmid=21791110 |doi-access=free }}{{Cite web|url=http://www.sharmalabuw.org/uploads/1/3/6/1/13619635/schwager_et_al._2015.pdf|title=Chelicerata - Prashant P. Sharma}}{{Cite web|url=http://www.science.marshall.edu/fet/euscorpius/p2011_120.pdf|title=Euscorpius - Marshall University}} These anterior seven somites (segments) of the opisthosoma are each covered by a hardened plate, the tergite, on the back surface. Underneath, somites 3 to 7 are armored with matching plates called sternites. The underside of somite 1 has two covering over the genital opening. Sternite 2 forms the basal plate bearing the comb-like pectines,{{sfn|Polis|1990|pp=13–14}} which function as sensory organs.{{cite journal |last1=Knowlton |first1=Elizabeth D. |last2=Gaffin |first2=Douglas D. |title=Functionally Redundant Peg Sensilla on the Scorpion Pecten |journal=Journal of Comparative Physiology A |publisher=Springer |volume=197 |issue=9 |year=2011 |issn=0340-7594 |doi=10.1007/s00359-011-0650-9 |pages=895–902|pmid=21647695 |s2cid=22123929 }}

The next four somites, 3 to 6, all possess two spiracles each. They serve as openings for the scorpion's respiratory organs, known as book lungs, and vary in shape.{{sfn|Polis|1990|p=15}}{{cite book |last=Wanninger |first=Andreas |title=Evolutionary Developmental Biology of Invertebrates 3: Ecdysozoa I: Non-Tetraconata |url=https://books.google.com/books?id=rxZcCgAAQBAJ&pg=PA105 |year=2015 |publisher=Springer |isbn=978-3-7091-1865-8 |page=105 |access-date=11 September 2017 |archive-date=5 August 2020 |archive-url=https://web.archive.org/web/20200805003251/https://books.google.com/books?id=rxZcCgAAQBAJ&pg=PA105 |url-status=live }} There are thus four pairs of book lungs; each consists of some 140 to 150 thin flaps or lamellae filled with air inside a pulmonary chamber, connected on the ventral side to an atrial chamber which opens into a spiracle. Bristles keep the lamellae from touching. A muscle opens the spiracle and widens the atrial chamber; dorsoventral muscles contract to constricts the pulmonary chamber, pushing air out, and relax to allow the chamber to refill.{{sfn|Polis|1990|pp=42–44}} The 7th and last somite lacks any notable structure.{{sfn|Polis|1990|p=15}}

The mesosoma contains the heart or "dorsal vessel" which is the center of the scorpion's open circulatory system. The heart is continuous with a deep arterial system which spreads throughout the body. Sinuses return deoxygenated blood (hemolymph) to the heart; the blood is re-oxygenated by cardiac pores. The mesosoma also houses the reproductive system. The female gonads are three or four tubes which are aligned and have two to four transverse anastomoses connecting them. These tubes create oocytes and house developing embryos. They connect to two oviducts which connect to a single atrium leading to the genital orifice.{{sfn|Stockmann|2015|pp=36, 45–46}} Males gonads are two pairs of cylindrical tubes with a ladder-like configuration; they contain spermatozoa-producing cysts. Both tubes end in a spermiduct, one on the opposite sides of the mesosoma. They connect to glandular symmetrical structures called paraxial organs, which end at the genital orifice. These create two halves of the chitin-based spermatophore which merge.{{sfn|Stockmann|2015|p=47}}{{cite journal |last1=Lautié |first1=N. |last2=Soranzo |first2=L. |last3=Lajarille |first3=M.-E. |last4=Stockmann |first4=R. |year=2007 |title=Paraxial Organ of a Scorpion: Structural and Ultrastructural Studies of Euscorpius tergestinus Paraxial Organ (Scorpiones, Euscorpiidae) |journal=Invertebrate Reproduction & Development |volume=51 |issue=2 |pages=77–90 |doi=10.1080/07924259.2008.9652258 |s2cid=84763256 }}

File:ScorpionBarb.jpg ]]

The "tail" or metasoma is divded into five segments and the telson, which is not strictly a segment. The five segments are merely body rings; they lack apparent sterna or terga, and are largest farthest from the center. These segments have keels, setae and bristles which may be used for taxonomic classification. The anus is at the back of the last segment, and is encircled by four anal papillae and the anal arch.{{sfn|Polis|1990|p=15}} The tails of some species contain light receptors.

The telson includes the vesicle, which contains a symmetrical pair of venom glands. Externally it bears the curved stinger, the hypodermic aculeus, equipped with sensory hairs. Venom ducts attached to the glands to transport the substance along the aculeus from the bulb of the gland to immediately near of the tip, where each of the paired ducts has its own venom pore.{{cite journal |last1=Yigit |first1=N. |last2=Benli |first2=M. |title=Fine Structural Analysis of the Stinger in Venom Apparatus of the Scorpion Euscorpius mingrelicus (Scorpiones: Euscorpiidae) |journal=Journal of Venomous Animals and Toxins Including Tropical Diseases |date=2010 |volume=16 |issue=1 |pages=76–86 |doi=10.1590/s1678-91992010005000003 |doi-access=free}} An intrinsic muscle system attached to the glands pumps venom through the stinger into the intended victim.{{sfn|Stockmann|2015|p=30}} The stinger contains metalloproteins with zinc, hardening the tip.{{cite book |last=Schofield |first=R. M. S. |year=2001 |chapter=Metals in cuticular structures |title=Scorpion Biology and Research |editor1=Brownell, P. H. |editor2=Polis, G. A. |pages=234–256 |location=New York |publisher=Oxford University Press |isbn=978-0195084344}} The optimal angle to launch a sting is around 30 degrees relative to the tip.{{cite journal |last1=van der Meijden |first1=Arie |last2=Kleinteich |first2=Thomas |title=A biomechanical view on stinger diversity in scorpions |journal=Journal of Anatomy |date=April 2017 |volume=230 |issue=4 |pages=497–509 |doi=10.1111/joa.12582|pmid=28028798 |pmc=5345679 |doi-access=free }}

File:Scorpion Centruroides limpidus (14587304901).jpg in its rocky shelter]]

Scorpion are typically nocturnal or crepuscular, finding shelter during the day in burrows, cracks and bark.{{sfn|Stockmann|2015|pp=40–41}} Many species dig an elementary shelter underneath tiny stones. Scorpions may use burrows build by other animals or dig their own; scorpion burrows vary in complexity and depth. Hadrurus species dig burrows over {{convert|2|m|abbr=on}} deep while Urodacus hoplurus digs in spirals. Digging is done using the mouth parts, claws and legs. In several species, particularly of the family Buthidae, individuals can be found in the same shelter; bark scorpions may gather in groups of up to 30 individuals. In some species, families of females and young sometimes aggregate.{{sfn|Stockmann|Ythier|2010|pp=146, 152–154}}

Scorpions prefer areas where the temperature remains in the range of {{convert|11|–|40|C|F}}, but may survive temperatures from well below freezing to desert heat.{{cite journal |last=Hadley |first=Neil F. |title=Water Relations of the Desert Scorpion, Hadrurus arizonensis |journal=Journal of Experimental Biology |year=1970 |volume=53 |issue=3 |pages=547–558 |doi=10.1242/jeb.53.3.547 |url=https://journals.biologists.com/jeb/article/53/3/547/21677/Water-Relations-of-the-Desert-Scorpion-Hadrurus |pmid=5487163 |bibcode=1970JExpB..53..547H |access-date=30 December 2006 |archive-date=6 April 2008 |archive-url=https://web.archive.org/web/20080406195500/http://jeb.biologists.org/cgi/reprint/53/3/547.pdf |url-status=live |url-access=subscription }}{{cite journal |last1=Hoshino |first1=K. |last2=Moura |first2=A. T. V. |last3=De Paula |first3=H. M. G. |title=Selection of Environmental Temperature by the Yellow Scorpion Tityus serrulatus Lutz & Mello, 1922 (Scorpiones, Buthidae) |journal=Journal of Venomous Animals and Toxins Including Tropical Diseases |year=2006 |volume=12 |issue=1 |pages=59–66 |doi=10.1590/S1678-91992006000100005 |doi-access=free |hdl=11449/68851 |hdl-access=free }} Scorpions can withstand intense heat: Leiurus quinquestriatus, Scorpio maurus and Hadrurus arizonensis can live in temperatures of {{convert|45|–|50|C|F|0|abbr=on}} if they are sufficiently hydrated. Desert species must deal with the extreme changes in temperature from sunrise to sunset or between seasons; Pectinibuthus birulai lives in a temperature range of {{convert|-30|–|50|C|F|0|abbr=on}}. Scorpions that live outside deserts prefer lower temperatures. The ability to withstand the cold may be related to the increase in the sugar trehalose when the temperature drops. Some species hibernate.{{sfn|Stockmann|2015|pp=42–43}} Scorpions have immunity to ionizing radiation and have survived nuclear tests in Algeria{{sfn|Stockmann|Ythier|2010|p=157}} and Nevada.{{Cite journal |last=Allred |first=Dorald M. |date=1973 |title=Effects of a Nuclear Detonation on Arthropods at the Nevada Test Site |url=https://scholarsarchive.byu.edu/byuscib/vol18/iss4/1?utm_source=scholarsarchive.byu.edu%2Fbyuscib%2Fvol18%2Fiss4%2F1&utm_medium=PDF&utm_campaign=PDFCoverPages |journal=Brigham Young University Science Bulletin |volume=18 |issue=4 |pages=1–20 |via=BYU SchoalarsArchive}}

Desert scorpions have several adaptations for water conservation. They excrete insoluble compounds such as xanthine, guanine, and uric acid, not requiring water for their removal from the body. Guanine is the main component and maximizes the amount of nitrogen excreted. A scorpion's cuticle holds in moisture via lipids and waxes from epidermal glands, and protects against ultraviolet radiation. Even when dehydrated, a scorpion can tolerate high osmotic pressure in its blood.{{cite book |last=Cowles |first=Jillian |title=Amazing Arachnids |publisher=Princeton University Press |year=2018 |page=33 |isbn=978-0-691-17658-1}} Desert scorpions get most of their moisture from the food they eat but some can absorb water from the sand if it is humid enough. Species that live in denser vegetation and in more moderate temperatures will drink from puddles or water accumulated on plants.{{sfn|Stockmann|Ythier|2010|p=156}}

File:Venom Squirting in Scorpions.svg to deter predators.]]

A scorpion uses its stinger both for killing prey and defense. Some species make direct, quick strikes with their tails while others make slower, more circular strikes which can more easily return the stinger to a position where it can strike again. Leiurus quinquestriatus can whip its tail at a speed of up to {{convert|128|cm/s|in/s|abbr=on}} in a defensive strike.{{cite journal |last1=Coelho |first1=P. |last2=Kaliontzopoulou |first2=A. |last3=Rasko |first3=M. |last4=van der Meijden |first4=A. |year=2017 |title=A 'Striking' Relationship: Scorpion Defensive Behaviour and its Relation to Morphology and Performance |journal=Functional Ecology |volume=31|issue=7 |pages=1390–1404 |doi=10.1111/1365-2435.12855|doi-access=free |bibcode=2017FuEco..31.1390C }}

Scorpions may be attacked by other arthropods like ants, spiders, solifugids and centipedes. Major predators include frogs, lizards, snakes, birds, and mammals.{{sfn|Stockmann|2015|pp=36–37}} Predators adapted for hunting scorpions include the grasshopper mouse and desert long-eared bat, which are immune to their venom.{{cite journal |last1=Thompson |first1=Benjamin |title=The Grasshopper Mouse and Bark Scorpion: Evolutionary Biology Meets Pain Modulation and Selective Receptor Inactivation |journal=The Journal of Undergraduate Neuroscience Education |date=June 2018 |volume=16 |issue=2 |pages=R51–R53 |pmid=30057511 |pmc=6057761 }} In one study, scorpion remains were found in 70% of the latter's droppings.{{Cite journal | last1=Holderied | first1=M. | last2=Korine | first2=C. | last3=Moritz | first3=T. | title=Hemprich's Long-eared Bat (Otonycteris hemprichii) as a Predator of Scorpions: Whispering Echolocation, Passive Gleaning and Prey Selection | journal=Journal of Comparative Physiology A | volume=197 | issue=5 | pages=425–433 | year=2010 | doi=10.1007/s00359-010-0608-3| pmid=21086132 | s2cid=25692517 }} Scorpions host parasites including mites, scuttle flies, nematodes and some bacteria. The immune system of scorpions is strong enough to resist several types of bacterial infections.{{sfn|Stockmann|2015|pp=38, 45}}

When threatened, a scorpion raises its claws and tail in a defensive posture. Some species stridulate to warn off predators by rubbing certain hairs, the stinger or the pectines.{{sfn|Stockmann|2015|p=37}} Certain species have a preference for using either the claws or stinger as defense, depending on the size of the appendages.{{cite journal |last1=van der Meijden |first1=A. |last2=Coelho |first2=P. L. |last3=Sousa |first3=P. |last4=Herrel |first4=A. |year=2013 |title=Choose your Weapon: Defensive Behavior is Associated with Morphology and Performance in Scorpions |journal=PLOS ONE |volume=8 |issue=11 |page=e78955 |doi=10.1371/journal.pone.0078955 |pmid=24236075 |pmc=3827323 |bibcode=2013PLoSO...878955V |doi-access=free }} A few scorpions, such as Parabuthus, Centruroides margaritatus, and Hadrurus arizonensis, squirt venom as {{convert|1|m|ft|sp=us}} which can injure predators in the eyes.{{sfn|Stockmann|Ythier|2010|p=90}} Some Ananteris species can shed parts of their tail to escape predators. The parts do not grow back, leaving them unable to sting and defecate, but they can still kill small prey and reproduce for at least eight months afterward.{{cite journal |last1=Mattoni |first1=C. I. |last2=García-Hernández |first2=S. |last3=Botero-Trujillo |first3=R. |last4=Ochoa |first4=J. A. |last5=Ojanguren-Affilastro |first5=A. A. |last6=Pinto-da-Rocha |first6=R. |last7=Prendini |first7=L. |year=2015 |title=Scorpion Sheds 'Tail' to Escape: Consequences and Implications of Autotomy in Scorpions (Buthidae: Ananteris) |journal=PLOS ONE |volume=10 |issue=1 |page=e0116639 |doi=10.1371/journal.pone.0116639|pmid=25629529 |pmc=4309614 |bibcode=2015PLoSO..1016639M |s2cid=17870490 |doi-access=free }}

File:Scorpion eating solifugid (Marshal Hedin).jpg ]]

Scorpions generally prey on insects, particularly grasshoppers, crickets, termites, beetles and wasps. They also prey on spiders, solifugids, woodlice and even small vertebrates including lizards, snakes and mammals. Species with large claws may prey on earthworms and mollusks. The majority of species are opportunistic and consume a variety of prey though some may be highly specialized; Isometroides vescus specializes on certain burrowing spiders. Prey size depends on the size of the species. Several scorpion species are sit-and-wait predators, which involves a hungry scorpion staying at or near the entrance to their burrow until prey arrives. Others actively search for prey. Scorpions detect their prey with mechanoreceptive and chemoreceptive hairs on their bodies and grab them with their claws. Small animals are killed merely with the claws, particularly by large-clawed species. Larger and more dangerous prey is given a sting.{{sfn|Stockmann|2015|pp=32–38}}{{cite web |last=Murray |first=Melissa |title=Scorpions |publisher=Australian Museum |url=https://australian.museum/learn/animals/spiders/scorpions/#:~:text=Scorpions%20are%20nocturnal%20hunters%2C%20feeding,and%20often%20occupying%20their%20burrows |date=3 December 2020 |access-date=13 December 2020 |archive-date=8 November 2020 |archive-url=https://web.archive.org/web/20201108102328/https://australian.museum/learn/animals/spiders/scorpions/#:~:text=Scorpions%20are%20nocturnal%20hunters%2C%20feeding,and%20often%20occupying%20their%20burrows |url-status=live }}

Scorpions, like other arachnids, digest their food externally. The chelicerae are used to rip small amounts of food off the prey item and into a pre-oral cavity underneath. The digestive juices from the gut are egested onto the food, and the digested food is then sucked into the gut. Any solid indigestible matter (such as exoskeleton fragments) is collected by setae in the pre-oral cavity and ejected. The sucked-in food is pumped into the midgut by the pharynx, where it is further digested. The waste is transported through the hindgut and out of the anus. Scorpions can eat large amounts of food during one meal. They can internally store food in a specialized organ and have a very low metabolic rate which enables some to survive up to a year without eating.{{sfn|Polis|1990|pp=296–298}}

File:Dancing scorpions-66970ep.jpg

Most scorpions reproduce sexually, with male and female individuals; species in some genera, such as Hottentotta and Tityus, and the species Centruroides gracilis, Liocheles australasiae, and Ananteris coineaui have been reported, not necessarily reliably, to reproduce through parthenogenesis, in which unfertilized eggs develop into living embryos.{{cite journal |last=Lourenço |first=Wilson R. |author-link=Wilson R. Lourenço |title=Parthenogenesis in Scorpions: Some History – New Data |journal=Journal of Venomous Animals and Toxins Including Tropical Diseases |volume=14 |issue=1 |year=2008 |issn=1678-9199 |doi=10.1590/S1678-91992008000100003 |doi-access=free}} Receptive females produce pheromones which are picked up by wandering males using their pectines to comb the substrate. Males begin courtship by shifting their bodies back and forth, with the legs still, a behavior known as juddering. This appears to produce ground vibrations that are picked up by the female.{{sfn|Stockmann|2015|p=47}}

The pair then make contact using their pedipalps, and perform a dance called the promenade à deux (French for "a walk for two"). In this dance, the male and female move around while facing each other, as the male searches for a suitable place to deposit his spermatophore. The courtship ritual can involve several other behaviors such as a cheliceral kiss, in which the male and female grasp each other's mouth-parts, arbre droit ("upright tree") where the partners elevate their posteriors and rub their tails together, and sexual stinging occurs, in which the male stings the female to subdue her. The dance may be minutes to hours long.{{sfn|Stockmann|2015|pp=47–50}}{{sfn|Stockmann|Ythier|2010|pp=126–128}}

When the male has located a suitably stable surface, he deposits the spermatophore and guides the female over it. This allows the spermatophore to enter her genital opercula, which triggers release of the sperm, thus fertilizing the female. A mating plug then forms in the female to block further matings until she gives birth. The male and female then abruptly separate.{{sfn|Stockmann|2015|pp=49–50}}{{sfn|Stockmann|Ythier|2010|pp=129–130}} Sexual cannibalism after mating has only been reported anecdotally in scorpions.{{cite journal |last=Peretti |first=A. |title=Sexual Cannibalism in Scorpions: Fact or Fiction? |journal=Biological Journal of the Linnean Society |volume=68 |issue=4 |year=1999 |pages=485–496 |issn=0024-4066 |doi=10.1111/j.1095-8312.1999.tb01184.x |doi-access=free}}

File:scorpionwithyoung.JPG female with young ]]

Gestation in scorpions can last for over a year in some species.{{sfn|Polis|1990|p=161}} They have two types of embryonic development; apoikogenic and katoikogenic. In the apoikogenic system, which is mainly found in the Buthidae, embryos develop in yolk-rich eggs inside follicles. The katoikogenic system is documented in Hemiscorpiidae, Scorpionidae and Diplocentridae, and involves the embryos growing in a diverticulum which has a teat-like structure for them to feed through.{{cite journal |last=Warburg |first=M. R. |year=2010 |title=Reproductive System of Female Scorpion: A Partial Review |journal=The Anatomical Record |volume=293 |issue=10 |pages=1738–1754 |doi=10.1002/ar.21219 |pmid=20687160 |s2cid=25391120 |doi-access=free}} Unlike the majority of arachnids, which are oviparous, hatching from eggs, scorpions seem to be universally viviparous, with live births; though apoikogenic species are ovoviviparous where young hatch from eggs inside the mother before being born.{{cite journal |last1=Warburg |first1=Michael R. |title=Pre- and Post-parturial Aspects of Scorpion Reproduction: a Review |journal=European Journal of Entomology |date=5 April 2012 |volume=109 |issue=2 |pages=139–146 |doi=10.14411/eje.2012.018 |doi-access=free }} They are unusual among terrestrial arthropods in the amount of care a female gives to her offspring.{{sfn|Polis|1990|p=6}} The size of a brood varies by species, from 3 to over 100. The body size of scorpions is not correlated either with brood size or with life cycle length.{{cite journal |last=Monge-Nájera |first=J. |year=2019 |title=Scorpion Body Size, Litter Characteristics, and Duration of the Life Cycle (Scorpiones) |journal=Cuadernos de Investigación UNED |volume=11 |issue=2 |pages=101–104}}

Before giving birth, the female raises the front of her body and positions her pedipalps and front legs under her for the young to fall through ("birth basket"). Each young exit through the genital opercula, expel the embryonic membrane, if any, and climb onto the mother's back where they remain until they have gone through at least one molt. The period before the first molt is called the pro-juvenile stage; the young lack the ability to eat or sting, but have suckers on their tarsi. This period lasts 5 to 25 days, depending on the species. The brood molt for the first time simultaneously in a process that lasts 6 to 8 hours, marking the beginning of the juvenile stage.{{cite book |last=Lourenço |first=Wilson R. |author-link=Wilson R. Lourenço |title=European Arachnology |chapter=Reproduction in Scorpions, with Special Reference to Parthenogenesis |year=2000 |editor1-first=S. |editor1-last=Toft |editor2-first=N. |editor2-last=Scharff |publisher=Aarhus University Press |isbn=978-877934-0015 |pages=74–76 |chapter-url=http://www.european-arachnology.org/wdp/wp-content/uploads/2015/08/071-085_Lourenco.pdf |access-date=14 December 2020 |archive-date=31 May 2021 |archive-url=https://web.archive.org/web/20210531031223/http://www.european-arachnology.org/wdp/wp-content/uploads/2015/08/071-085_Lourenco.pdf |url-status=live }}

Juvenile stages or instars generally resemble smaller versions of adults, with pincers, hairs and stingers. They are still soft and colorless, and thus continue to ride on their mother's back for protection. As days pass, they become harder and more pigmented. They may leave their mother temporarily, returning when they sense potential danger. When fully hardened, young can hunt and kill on their own and eventually become fully independent.{{sfn|Stockmann|2015|p=54}} A scorpion goes through an average of six molts before maturing, which may not occur until it is 6 to 83 months old, depending on the species. They can reach an age of 25 years.{{sfn|Polis|1990|p=161}}

{{multiple image|image1=Sorpion Under Blacklight edit.jpg|caption1=This black emperor scorpion (Pandinus imperator) fluoresces light blue.|width1=200|image2=Scorpion with babies in UV.jpg|caption2=The mother glows bright teal, the young a dull grey.|width2=113}}

Scorpions glow a vibrant blue-green when exposed to certain wavelengths of ultraviolet light, such as that produced by a black light, due to fluorescent chemicals such as beta-carboline in the cuticle. Accordingly, a hand-held ultraviolet lamp has long been a standard tool for nocturnal field surveys of these animals. Fluorescence occurs as a result of sclerotization and increases in intensity with each successive instar.{{cite journal |first1=Shawn J. |last1=Stachel |first2=Scott A. |last2=Stockwell |first3=David L. |last3=Van Vranken |date=August 1999 |title=The Fluorescence of Scorpions and Cataractogenesis |journal=Chemistry & Biology |volume=6 |pages=531–539 |doi=10.1016/S1074-5521(99)80085-4 |pmid=10421760 |issue=8 |doi-access=free }} This fluorescence may function in detecting light.{{cite journal |last1=Gaffinr |first1=Douglas D. |last2=Bumm |first2=Lloyd A. |last3=Taylor |first3=Matthew S. |last4=Popokina |first4=Nataliya V. |last5=Mann |first5=Shivani |year=2012 |title=Scorpion Fluorescence and Reaction to Light |journal=Animal Behaviour |issue=2 |doi=10.1016/j.anbehav.2011.11.014 |volume=83 |pages=429–436 |s2cid=17041988 |url=https://zenodo.org/record/895450 |access-date=18 May 2018 |archive-date=6 November 2020 |archive-url=https://web.archive.org/web/20201106153700/https://zenodo.org/record/895450 |url-status=live }}

{{anchor|In culture}}

{{further|Human uses of scorpions}}

{{main article|Scorpion sting}}

File:Bbasgen-scorpion-front.jpg, one of the few species whose venom is deadly to humans]]

Scorpion venom serves to kill or paralyze prey rapidly, but only 25 species have venom that is deadly to humans, the most dangerous being Leiurus quinquestriatus. People with allergies are especially at risk, but otherwise symptoms typically last no more than two days for non-deadly species.{{cite web |url=https://www.cdc.gov/niosh/topics/insects/scorpions.html |title=Insects and Scorpions |publisher=NIOSH |date=1 July 2016 |access-date=15 July 2016 |archive-date=29 July 2016 |archive-url=https://web.archive.org/web/20160729121849/http://www.cdc.gov/niosh/topics/insects/scorpions.html |url-status=live }} Deaths from lethal stings are caused by excessive autonomic activity and toxic effects on cardiovascular or neuromuscular systems. Antivenom is used to counter scorpion envenomations, along with vasodilators to treat the cardiovascular system and benzodiazepines for the neuromuscular system. Severe hypersensitivity reactions including anaphylaxis to scorpion antivenin can occur, though rarely.{{cite journal |last1=Bhoite |first1=R. R. |last2=Bhoite |first2=G. R. |last3=Bagdure |first3=D. N. |last4=Bawaskar |first4=H. S. |title=Anaphylaxis to Scorpion Antivenin and its Management Following Envenomation by Indian Red Scorpion, Mesobuthus tamulus |journal=Indian Journal of Critical Care Medicine |volume=19 |issue=9 |pages=547–549 |year=2015 |doi=10.4103/0972-5229.164807 |pmc=4578200 |pmid=26430342 |doi-access=free }}

Scorpion stings are a public health problem, particularly in the tropical and subtropical regions of the Americas, North Africa, the Middle East and India. Around 1.5 million scorpion envenomations occur each year, with around 2,600 deaths.{{cite journal |last1=Feola |first1=A. |last2=Perrone |first2=M. A. |last3=Piscopo |first3=A. |last4=Casella |first4=F. |last5=Della Pietra |first5=B. |last6=Di Mizio |first6=G. |year=2020 |title=Autopsy Findings in Case of Fatal Scorpion Sting: A Systematic Review of the Literature |journal=Healthcare |volume=8 |issue=3 |page=325 |doi=10.3390/healthcare8030325|pmid=32899951 |pmc=7551928 |doi-access=free }}{{sfn|Stockmann|Ythier|2010|pp=163–164}}{{cite journal |last1=Santos |first1=Maria S.V. |last2=Silva |first2=Cláudio G.L. |last3=Neto |first3=Basílio Silva |last4=Grangeiro Júnior |first4=Cícero R.P. |last5=Lopes |first5=Victor H.G. |last6=Teixeira Júnior |first6=Antônio G. |last7=Bezerra |first7=Deryk A. |last8=Luna |first8=João V.C.P. |last9=Cordeiro |first9=Josué B. |last10=Júnior |first10=Jucier Gonçalves |last11=Lima |first11=Marcos A.P. |title=Clinical and Epidemiological Aspects of Scorpionism in the World: A Systematic Review |journal=Wilderness & Environmental Medicine |volume=27 |issue=4 |year=2016 |pages=504–518 |issn=1080-6032 |doi=10.1016/j.wem.2016.08.003 |pmid=27912864 |url=https://www.wemjournal.org/article/S1080-6032(16)30214-9/pdf |doi-access=free |access-date=8 December 2020 |archive-date=31 May 2021 |archive-url=https://web.archive.org/web/20210531031227/https://www.wemjournal.org/article/S1080-6032%2816%2930214-9/pdf |url-status=live }} Mexico is one of the most affected countries, with the highest biodiversity of scorpions in the world, some 200,000 envenomations per year and at least 300 deaths.{{cite journal |last1=Dehesa-Dávila |first1=Manuel |last2=Possani |first2=Lourival D. |title=Scorpionism and Serotherapy in Mexico |journal=Toxicon |volume=32 |issue=9 |year=1994 |pages=1015–1018 |issn=0041-0101 |doi=10.1016/0041-0101(94)90383-2|pmid=7801335 |bibcode=1994Txcn...32.1015D }}{{cite journal |last1=Santibáñez-López |first1=Carlos |last2=Francke |first2=Oscar |last3=Ureta |first3=Carolina |last4=Possani |first4=Lourival |title=Scorpions from Mexico: From Species Diversity to Venom Complexity |journal=Toxins |volume=8 |issue=1 |year=2015 |pages=2 |issn=2072-6651 |doi=10.3390/toxins8010002|pmid=26712787 |pmc=4728524 |doi-access=free }}

Efforts are made to prevent envenomation and to control scorpion populations. Prevention encompasses personal activities such as checking shoes and clothes before putting them on, not walking in bare feet or sandals, and filling in holes and cracks where scorpions might nest. Street lighting reduces scorpion activity. Control may involve the use of insecticides such as pyrethroids, or gathering scorpions manually with the help of ultraviolet lights. Domestic predators of scorpions, such as chickens and turkeys, can help to reduce the risk to a household.{{sfn|Stockmann|Ythier|2010|pp=163–164}}

File:Chlorotoxin.png's powerful venom contains the 36-amino acid peptide chlorotoxin (ribbon diagram shown). This blocks small-conductance chloride channels, immobilizing its prey.]]

Scorpion venom is a mixture of neurotoxins; most of these are peptides, chains of amino acids.{{cite book |last1=Rodríguez de la Vega |first1=Ricardo C. |last2=Vidal |first2=Nicolas |last3=Possani |first3=Lourival D. |chapter=Scorpion Peptides |editor-first=Abba J. |editor-last=Kastin |title=Handbook of Biologically Active Peptides |publisher=Academic Press |edition=2nd |year=2013 |isbn=978-0-12-385095-9 |pages=423–429 |doi=10.1016/B978-0-12-385095-9.00059-2}} Many of them interfere with membrane channels that transport sodium, potassium, calcium, or chloride ions. These channels are essential for nerve conduction, muscle contraction and many other biological processes. Some of these molecules may be useful in medical research and might lead to the development of new disease treatments. Among their potential therapeutic uses are as analgesic, anti-cancer, antibacterial, antifungal, antiviral, antiparasitic, bradykinin-potentiating, and immunosuppressive drugs. As of 2020, no scorpion toxin-based drug is for sale, though chlorotoxin is being trialled for use against glioma, a brain cancer.{{cite journal |last1=Ahmadi |first1=Shirin |last2=Knerr |first2=Julius M. |last3=Argemi |first3=Lídia |last4=Bordon |first4=Karla C. F. |last5=Pucca |first5=Manuela B. |last6=Cerni |first6=Felipe A. |last7=Arantes |first7=Eliane C. |last8=Çalışkan |first8=Figen |last9=Laustsen |first9=Andreas H. |title=Scorpion Venom: Detriments and Benefits |journal=Biomedicines |publisher=MDPI AG |volume=8 |issue=5 |date=12 May 2020 |issn=2227-9059 |doi=10.3390/biomedicines8050118 |pmid=32408604 |pmc=7277529 |page=118|doi-access=free }}

Scorpions are eaten in West Africa, Myanmar{{sfn|Stockmann|Ythier|2010|p=147}} and East Asia. Fried scorpion is traditionally eaten in Shandong, China.{{cite web |first=Matthew |last=Forney |date=11 June 2008 |url=https://www.nytimes.com/2008/06/11/dining/11china.html |title=Scorpions for Breakfast and Snails for Dinner |website=The New York Times |access-date=23 February 2017 |archive-date=27 November 2020 |archive-url=https://web.archive.org/web/20201127002256/https://www.nytimes.com/2008/06/11/dining/11china.html |url-status=live }} There, scorpions can be cooked and eaten in a variety of ways, including roasting, frying, grilling, raw, or alive. The stingers are typically not removed, since heat negates the harmful effects of the venom.{{Cite web |date=15 May 2014 |last1=Albers |first1=Susan |title=How to Mindfully Eat a Scorpion |url=https://www.huffpost.com/entry/how-mindfully-eat-a-scorp_b_5321948 |access-date=29 July 2020 |website=HuffPost |archive-date=13 August 2020 |archive-url=https://web.archive.org/web/20200813234226/https://www.huffpost.com/entry/how-mindfully-eat-a-scorp_b_5321948 |url-status=live }} In Thailand, scorpions are not eaten as often as other arthropods, such as grasshoppers, but they are sometimes fried as street food.{{cite web |last1=Fernquest |first1=Jon |title=Fried Scorpion Anyone? |url=https://www.bangkokpost.com/learning/advanced/915769/fried-scorpion-anyone- |publisher=Bangkok Post |access-date=7 December 2020 |date=30 March 2016 |archive-date=31 May 2021 |archive-url=https://web.archive.org/web/20210531031308/https://www.bangkokpost.com/learning/advanced/915769/fried-scorpion-anyone- |url-status=live }} They are used in Vietnam to make snake wine (scorpion wine).{{cite journal |title=The Quality of Alcohol Products in Vietnam and Its Implications for Public Health |first1=Dirk W. |last1=Lachenmeier |first2=Pham Thi Hoang |last2=Anh |first3=Svetlana |last3=Popova |first4=Jürgen |last4=Rehm |date=11 August 2009 |journal=International Journal of Environmental Research and Public Health |volume=6 |issue=8 |pages=2090–2101 |doi=10.3390/ijerph6082090 |pmid=19742208 |pmc=2738875|doi-access=free }}

Scorpions are often kept as pets. They are relatively simple to keep, the main requirements being a secure enclosure such as a glass terrarium with a lockable lid and the appropriate temperature and humidity for the chosen species, which typically means installing a heating mat and spraying regularly with a little water. The substrate needs to resemble that of the species' natural environment, such as peat for forest species, or lateritic sand for burrowing desert species. Scorpions in the genera Pandinus and Heterometrus are docile enough to handle. A large Pandinus may consume up to three crickets each week. Cannibalism is more common in captivity than in the wild and can be minimized by providing many small shelters within the enclosure and ensuring there is plenty of prey.{{cite web |title=Scorpion Caresheet |url=https://www.amentsoc.org/insects/caresheets/scorpions.html |publisher=Amateur Entomologists' Society |access-date=19 November 2020 |archive-date=1 November 2020 |archive-url=https://web.archive.org/web/20201101091350/https://www.amentsoc.org/insects/caresheets/scorpions.html |url-status=live }}{{sfn|Stockmann|Ythier|2010|pp=144, 173–177}} The pet trade has threatened wild populations of some scorpion species, particularly Androctonus australis and Pandinus imperator.{{sfn|Pryke|2016|pp=187–189}}

File:Egyptian - Figure of Isis-Serget as Scorpion - Walters 54546 - Side A (cropped).jpg|Late period bronze figure of Isis-Serket

Scorpion and snake fighting Anglo-Saxon c 1050.jpg|"Scorpion and snake fighting", Anglo-Saxon Herbal, c. 1050

File:Sidney Hall - Urania's Mirror - Scorpio.jpg|The constellation Scorpius, depicted in Urania's Mirror as "Scorpio", London, c. 1825

File:Scorpion kilim motif.jpg|A scorpion motif (two types shown) was often woven into Turkish kilim flatweave carpets, for protection from their sting.

File:Mr-yoga-stretched-out-scorpion.jpg.png|Scorpion pose in yoga has one or both legs pointing forward over the head, like a scorpion's tail.

The scorpion is a culturally significant animal. One of the earliest occurrences of the scorpion in culture is its inclusion, as Scorpio, in the 12 signs of the Zodiac by Babylonian astronomers during the Chaldean period.{{sfn|Polis|1990|p=462}}

In ancient Egypt, the goddess Serket, who protected the Pharaoh, was often depicted as a scorpion.{{cite web |url=https://www.britishmuseum.org/collection/term/BIOG55814 |title=Serqet |publisher=British Museum |access-date=10 December 2020 |archive-date=1 December 2020 |archive-url=https://web.archive.org/web/20201201174344/https://www.britishmuseum.org/collection/term/BIOG55814 |url-status=live }} In Greek mythology, Artemis or Gaia sent a giant scorpion named Scorpius to kill the hunter Orion, who had said he would kill all the world's animals. Orion and the scorpion both became constellations; as enemies they were placed on opposite sides of the world, so when one rises in the sky, the other sets.{{cite book |last1=Kerényi |first1=C. |author1-link=Károly Kerényi |title=The Gods of the Greens |date=1974 |publisher=Thames and Hudson |isbn=978-0-500-27048-6 |page=203 |chapter=Stories of Orion}}{{sfn|Stockmann|Ythier|2010|p=179}}{{sfn|Pryke|2016|pp=126–129}}

Scorpions are mentioned in the Bible and the Talmud as symbols of danger and maliciousness.{{sfn|Stockmann|Ythier|2010|p=179}} The Sanskrit medical encyclopedia, The Suśrutasaṃhita, datable to before 500 CE, contains a detailed description of thirty types of scorpion, classified according to the levels of toxicity of their stings and their colours. Treatments for scorpion-sting are described.{{Cite book |last=Sharma |first=Priya Vrat |url=http://n2t.net/ark:/13960/s2gpx8453k1 |title=Suśruta-Saṃhitā with English Translation of Text and Ḍalhaṇa's Commentary Along With Critical Notes |publisher=Chaukhambha Visvabharati |year=2001 |volume=3 |location=Varanasi |pages=87–91}} Scorpions have also appeared as a motif in art, especially in Islamic art in the Middle East.{{cite journal |first=Jürgen Wasim |last=Frembgen |year=2004 |title=The Scorpion in Muslim Folklore |journal=Asian Folklore Studies |volume=63 |issue=1 |pages=95–123 |url=http://nirc.nanzan-u.ac.jp/nfile/631 |access-date=12 August 2014 |archive-date=16 March 2014 |archive-url=https://web.archive.org/web/20140316232038/http://nirc.nanzan-u.ac.jp/nfile/631 |url-status=live }}

A scorpion motif is often woven into Turkish kilim flatweave carpets, for protection from their sting.{{cite book |last=Erbek |first=Güran |title=Kilim Catalogue No. 1 |publisher=May Selçuk A. S. |edition=1st |date=1998 |at="Motifs", before page 1}} The scorpion is perceived both as an embodiment of evil and as a protective force such as a dervish's powers to combat evil. In Muslim folklore, the scorpion portrays human sexuality. Scorpions are used in folk medicine in South Asia, especially in antidotes for scorpion stings.

The fable of The Scorpion and the Frog has been interpreted as showing that vicious people cannot resist hurting others, even when it is not in their interests.{{cite journal |author=Takeda, A. |url=https://publikationen.uni-tuebingen.de/xmlui/bitstream/handle/10900/47008/pdf/Arata_Takeda_Blumenreiche_Handelswege.pdf |title=Blumenreiche Handelswege: Ost-westliche Streifzüge auf den Spuren der Fabel Der Skorpion und der Frosch |trans-title=Flowery Trade Routes: East-Western forays into the footsteps of the fable The Scorpion and the Frog |journal=Deutsche Vierteljahrsschrift für Literaturwissenschaft und Geistesgeschichte |language=de |year=2011 |volume=85 |issue=1 |pages=124–152 |doi=10.1007/BF03374756 |s2cid=170169337 |quotation=(German) Die Moral der Fabel besagt: Manche Menschen handeln von Natur aus mörderisch und selbst-mörderisch zugleich. (English) The moral of the fable says: Some people act naturally murderous and self-murderous at the same time. |access-date=9 December 2020 |archive-date=5 November 2020 |archive-url=https://web.archive.org/web/20201105152526/https://publikationen.uni-tuebingen.de/xmlui/bitstream/handle/10900/47008/pdf/Arata_Takeda_Blumenreiche_Handelswege.pdf |url-status=live }} More recently, the action in John Steinbeck's 1947 novella The Pearl centers on a poor pearl fisherman's attempts to save his infant son from a scorpion sting, only to lose him to human violence.{{cite journal |last1=Meyer |first1=Michael |title=Diamond in the Rough: Steinbeck's Multifaceted Pearl |journal=The Steinbeck Review |date=2005 |volume=2 |issue=2 (Fall 2005) |pages=42–56 |jstor=41581982}} Scorpions have equally appeared in western artforms including film and poetry: the surrealist filmmaker Luis Buñuel made symbolic use of scorpions in his 1930 classic L'Age d'or (The Golden Age).{{cite book |first=Allen S. |last=Weiss |chapter=Between the sign of the scorpion and the sign of the cross: L'Age d'or |pages=[https://archive.org/details/isbn_9780262611213/page/159 159] |editor-first=Rudolf E. |editor-last=Kuenzli |year=1996 |title=Dada and Surrealist Film |publisher=MIT Press |isbn=978-0-262-61121-3 |chapter-url=https://books.google.com/books?id=ZDl6HsqFJwAC&pg=PA159 |url=https://archive.org/details/isbn_9780262611213/page/159 }}

Since classical times, the scorpion with its powerful stinger has been used to provide a name for weapons. In the Roman army, the scorpio was a torsion siege engine used to shoot a projectile.Vitruvius, De Architectura, X:10:1–6. The British Army's FV101 Scorpion was an armored reconnaissance vehicle or light tank in service from 1972 to 1994.{{cite web |publisher=Jane's Information Group |title=Scorpion |url=http://www.janes.com/defence/land_forces/supplement/lav/lav_scorpion.shtml |access-date=16 November 2020 |archive-url=https://web.archive.org/web/20080221171530/https://www.janes.com/defence/land_forces/supplement/lav/lav_scorpion.shtml |archive-date=21 February 2008 |url-status=dead}} A version of the Matilda II tank, fitted with a flail to clear mines, was named the Matilda Scorpion.{{cite book |last=Fletcher |first=David |title=British Battle Tanks: British-made Tanks of World War II |url=https://books.google.com/books?id=H7EvDwAAQBAJ&pg=PA37 |year=2017 |publisher=Bloomsbury |isbn=978-1-4728-2003-7 |page=37 |access-date=27 June 2020 |archive-date=31 July 2020 |archive-url=https://web.archive.org/web/20200731185805/https://books.google.com/books?id=H7EvDwAAQBAJ&pg=PA37 |url-status=live }}

Several ships of the Royal Navy and of the US Navy have been named Scorpion including an 18-gun sloop in 1803,{{cite book |last=Winfield |first=Rif |title=British Warships in the Age of Sail 1793–1817: Design, Construction, Careers and Fates |publisher=Seaforth |year=2008 |isbn=978-1-86176-246-7 |page=291}} a turret ship in 1863,{{cite book |last=Parkes |first=Oscar |title=British Battleships |publisher=Naval Institute Press |year=1990 |edition=reprint of the 1957 |isbn=1-55750-075-4 |pages=78–79}} a patrol yacht in 1898,{{cite journal |date=10 September 1896 |title=[untitled] |journal=Marine Review |volume=14 |issue=11 |location=Cleveland, Ohio |page=1}} a destroyer in 1910,{{cite news |title=[untitled] |department=Naval and Military Intelligence |work=The Times |location=London |date=31 August 1910 |page=5 |url=https://www.newspapers.com/clip/64444910/scorpion-tbd/ |access-date=2 December 2020 |archive-date=31 May 2021 |archive-url=https://web.archive.org/web/20210531031226/https://www.newspapers.com/clip/64444910/scorpion-tbd/ |url-status=live }} and a nuclear submarine in 1960.{{cite web |url=http://www.csp.navy.mil/othboats/589.htm |title=USS Scorpion (SSN 589) May 27, 1968 – 99 Men Lost |date=2007 |website=United States Navy |access-date=9 April 2008 |url-status=dead |archive-url=https://web.archive.org/web/20080312204810/http://www.csp.navy.mil/othboats/589.htm |archive-date=12 March 2008 }}

The scorpion has served as the name or symbol of products and brands including Italy's Abarth racing cars{{cite web |title=The History of Abarth's Logo |url=http://www.museodelmarchioitaliano.com/route1/abarth.php |publisher=Museo del marchio italiano |access-date=16 November 2020 |quote=The company logo has been the scorpion since the very start; Carlo Abarth did not only want it as a reference to his zodiac sign, but also because it was an original and hard to imitate logo. At the beginning the scorpion was free from any contour and featured the typo "Abarth & Co.- Torino". In 1954 a shield was added, as symbol of victory and passion; |archive-date=3 July 2020 |archive-url=https://web.archive.org/web/20200703181150/http://www.museodelmarchioitaliano.com/route1/abarth.php |url-status=live }} and a Montesa scrambler motorcycle.{{cite web |last=Salvadori |first=Clement |title=Retrospective: 1974–1977 Montesa Cota 247-T |url=https://ridermagazine.com/2019/01/17/retrospective-1974-1977-montesa-cota-247-t/ |work=Rider Magazine |access-date=25 June 2020 |date=17 January 2019 |quote=Permanyer persisted, built larger engines, and in 1965 showed the 247cc engine (21 horsepower at 7,000 rpm) in a Scorpion motocrosser. |archive-date=27 June 2020 |archive-url=https://web.archive.org/web/20200627063031/https://ridermagazine.com/2019/01/17/retrospective-1974-1977-montesa-cota-247-t/ |url-status=live }}

A hand- or forearm-balancing asana in modern yoga as exercise with the back arched and one or both legs pointing forward over the head in the manner of the scorpion's tail is called Scorpion pose.{{cite journal |author=Anon |last2=Budig |first2=Kathryn |title=Kathryn Budig Challenge Pose: Scorpion in Forearm Balance |journal=Yoga Journal |date=1 October 2012 |url=https://www.yogajournal.com/practice/vrischika-in-pincha-mayurasana |access-date=25 June 2020 |archive-date=27 June 2020 |archive-url=https://web.archive.org/web/20200627182355/https://www.yogajournal.com/practice/vrischika-in-pincha-mayurasana |url-status=live }}{{cite book |last=Iyengar |first=B. K. S. |author-link=B. K. S. Iyengar |title=Light on Yoga |publisher=Thorsons |year=1991 |isbn=978-0-00-714516-4 |oclc=51315708 |pages=386–388}}

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{{reflist}}

• {{cite book |last=Polis |first=Gary |title=The Biology of Scorpions |publisher=Stanford University Press |year=1990 |isbn=978-0-8047-1249-1 |oclc=18991506}}
• {{cite book |last=Pryke |first=L. M. |year=2016 |title=Scorpion |publisher=Reaktion Books |isbn=978-1780236254}}
• {{cite book |last1=Stockmann |first1=Roland |last2=Ythier |first2=Eric |title=Scorpions of the World |publisher=N. A. P. Editions |year=2010 |isbn=978-2913688117}}
• {{cite book |last=Stockmann |first=Roland |year=2015 |contribution=Introduction to Scorpion Biology and Ecology |editor-last=Gopalakrishnakone |editor-first=P. |editor2=Possani, L. |editor3=F. Schwartz, E. |editor4=Rodríguez de la Vega, R. |title=Scorpion Venoms |publisher=Springer |pages=25–59 |isbn=978-94-007-6403-3}}

• [http://scorpion.amnh.org/index.html American Museum of Natural History - Scorpion Systematics Research Group]
• [https://www.cdc.gov/niosh/topics/insects/ CDC – Insects and Scorpions – NIOSH Workplace Safety and Health Topic]

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Category:Wenlock first appearances

Category:Extant Silurian first appearances