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Revision as of 10:38, 21 January 2024 view source Throowa (talk \| contribs) 352 edits created a new paragraph "Potential distinction", which will likely be controversial, clarified the examples with adverbs "gradually" and "rapidly", deleted a redundant conversion of temperature, reason: the example is too long, and the exact value is not crucial. Tag: Visual edit ← Previous edit		Latest revision as of 15:34, 25 June 2025 view source BALDD29 (talk \| contribs) 327 edits No edit summary Tags: Mobile edit Mobile web edit
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Line 1: {{Short description\|Transition ~~of a substance directly~~ from ~~the~~ solid to ~~the~~gas ~~gas~~without ~~state~~melting}} {{Redirect\|Sublimates\|\|Sublimation (disambiguation){{!}}Sublimation}} {{distinguish\|subliminal stimuli}} {{pp\|small=yes}} Line 13: (also similar to evaporation, just higher pressure) (top left of solid in phase diagram) These three cases jointly exhaust the solid space in the phrase diagram. This ~~make~~makes sense, after all, technically, all solids sublime (depending mostly on vapour pressure, which is very situational). One may notice there is a fourth case in the solid space, that is, at the solid-liquid boundary. It is uncertain if the solid is still ~~considered~~defined as subliming WHILE melting, and in case it is, it would be subliming ~~gradually, those who know PLEASE CLARIFY~~rapidly. --> <!-- Line 34: [[File:Nickelocen an einem Kühlfinger.jpg\|thumb\|right\|Dark green [[crystals]] of [[nickelocene]], sublimed and freshly deposited on a [[cold finger]]]] [[File:Sublimation of iodine.webm\|thumb\|Sublimation of [[iodine]]]] '''Sublimation''' is the [[Phase transition\|transition of a substance]] directly from the [[solid]] to the [[gas]] state, without passing through the [[liquid]] state.<ref>{{cite book \|last1=Whitten \|first1=Kenneth W. \|last2=Gailey \|first2=Kenneth D. \|last3=Davis \|first3=Raymond E. \|title=General chemistry \|url=https://archive.org/details/generalchemistry00whit_0 \|url-access=registration \|date=1992 \|publisher=Saunders College Publishing \|isbn=0-03-072373-6 \|page=[https://archive.org/details/generalchemistry00whit_0/page/475 475] \|edition=4th}}</ref> The verb form of sublimation is ''sublime'', or less preferably, ''sublimate''.<ref name=":0">{{cite Merriam-Webster\|Sublimate}}</ref> ''Sublimate'' also refers to the product obtained by sublimation.<ref name=":0" /><ref>[https://www.collinsdictionary.com/dictionary/english/sublimate "Sublimate"]. [[Collins English Dictionary#CollinsDictionary.com\|CollinsDictionary.com Dictionary]].</ref> The point at which sublimation occurs rapidly (for further details, see [[~~Sublimation (phase transition)~~#False correspondence with vaporization\|below]]) is called critical sublimation point, or simply [[sublimation point]]. Notable examples include sublimation of [[dry ice]] at room temperature and atmospheric pressure, and that of solid [[iodine]] with heating. The reverse process of sublimation is [[deposition (phase transition)\|''deposition'']] (also called ''desublimation''), in which a substance passes directly from a gas to a solid phase, without passing through the liquid state.<ref name="DepositionDef">{{cite journal \|title=Controlling condensation and frost growth with chemical micropatterns \|first1=Jonathan B. \|last1=Boreyko \|first2=Ryan R. \|last2=Hansen \|first3=Kevin R. \|last3=Murphy \|first4=Saurabh \|last4=Nath \|first5=Scott T. \|last5=Retterer \|first6=C. Patrick \|last6=Collier \|journal=Scientific Reports \|year=2016 \|volume=6 \|pages=19131 \|doi=10.1038/srep19131 \|pmid=26796663 \|pmc=4726256 \|bibcode=2016NatSR...619131B}}</ref> ~~All~~Technically, all solids may sublime, though most sublime at extremely low rates that are hardly detectable under usual conditions. At [[standard conditions for temperature and pressure\|normal pressures]], most [[chemical compound]]s and [[chemical element\|elements]] possess three different states at different [[temperature]]s. In these cases, the transition from the [[solid]] to the [[gas]] state requires an intermediate liquid state. The pressure referred to is the ''[[partial pressure]]\|''partial'' pressure]] of the substance, not the ''total'' (e.g. atmospheric) pressure of the entire system. Thus, any solid can sublime if its [[vapour pressure]] is higher than the surrounding partial pressure of the same substance, and in some cases, ~~sublimes~~sublimation occurs at an appreciable rate (e.g. water ice just below 0 °C). For some substances, such as [[carbon]] and [[arsenic]], sublimation from solid state is much more achievable than [[evaporation]] from liquid state and it is difficult to obtain them as liquids. This is because the pressure of their [[triple point]] in its [[phase diagram]] (which corresponds to the lowest pressure at which the substance can exist as a liquid) is very high. Line 47: == Confusions == While the definition of sublimation is simple, itthere is often ~~confused~~confusion as to what counts as a sublimation. === False correspondence with vaporization === ~~While~~ [[~~vaporization~~Vaporization]] (from liquid to gas) is divided into two types;: vaporization on the surface of the liquid is called [[evaporation]];, and vaporization at the boiling point with formation of bubbles in the interior of the liquid is called [[boiling]],. However there is ''no'' such distinction for the solid-to-gas transition., ~~Solid-to-gas transition~~which is always called sublimation in both corresponding cases. ==== Potential distinction ==== For clarification, a distinction between the two corresponding cases is needed. With reference to a [[phase diagram]], the sublimation that occurs left of the solid-gas boundary, the triple point or the solid-liquid boundary (corresponding to evaporation in vaporization) may be called ''gradual sublimation''; and the substance ''~~sublime~~sublimes gradually'', regardless of rate. The sublimation that occurs at the solid-gas boundary (critical sublimation point) (corresponding to boiling in vaporization) may be called ''rapid sublimation'', and the substance ''~~sublime~~sublimes rapidly''. ~~Note that both the~~The words "gradual" and "rapid" have acquired special meanings in ~~such~~this context and no longer ~~describes~~describe the rate of sublimation.{{cn\|date=April 2024}}<!-- This distinction is used only on this page and nowhere else, to minimize confusion. If there is a better distinction, change it along with the examples. If this violates the policy of Wikipedia, please delete this paragraph ~~and nothing else~~, and if possible, also provide a better solution. --> === Misuse for chemical reaction === Line 59: === Historical definition === Sublimation is historically used as a generic term to describe a two-step phase transition ― a solid-to-gas transition (sublimation in a more precise definition) followed by a gas-to-solid transition ([[deposition (phase transition)\|deposition]]).<ref>{{Dictionary.com\|Sublime}}</ref><ref>[https://www.collinsdictionary.com/dictionary/english/sublime "Sublime"]. [[Collins English Dictionary#CollinsDictionary.com\|CollinsDictionary.com Dictionary]].</ref> (See [[~~Sublimation (phase transition)~~#Historical usage\|below]]) ==Examples== [[File:Comparison carbon dioxide water phase diagrams.svg\|thumb\|upright=2\|Comparison of phase diagrams of carbon dioxide (red) and water (blue) showing the carbon dioxide sublimation point (middle-left) at 1 atmosphere. As dry ice is heated, it crosses this point along the bold horizontal line from the solid phase directly into the gaseous phase. Water, on the other hand, passes through a liquid phase at 1 atmosphere.]] The examples shown are substances that noticeably sublime under certain conditions. ===Carbon dioxide=== Line 69 ⟶ 70: ===Water=== [[Snow]] and [[ice]] sublime gradually at temperatures below the solid-liquid boundary (melting point) (generally 0 °C), and at partial pressures below the triple point pressure of {{convert\|612\|Pa\|atm\|abbr=on}}, at a low rate.<ref>{{cite journal \|last=Fassnacht \|first=S. R. \|year=2004 \|title=Estimating Alter-shielded gauge snowfall undercatch, snowpack sublimation, and blowing snow transport at six sites in the coterminous USA \|journal=Hydrol. Process. \|doi=10.1002/hyp.5806 \|bibcode=2004HyPr...18.3481F \|volume=18 \|issue=18 \|pages=3481–3492\|s2cid=129927018 }}</ref> In [[freeze-drying]], the material to be dehydrated is frozen and its water is allowed to sublime under reduced pressure or vacuum. The loss of snow from a [[snowfield]] during a cold spell is often caused by sunshine acting directly on the upper layers of the snow. Sublimation of ice is a factor to the erosive wear of [[glacier ice]], ~~also~~known ~~called~~as [[ablation]] in [[glaciology]].<ref>{{~~citation~~Cite web ~~needed~~\|url=http://amsglossary.allenpress.com/glossary/search?p=1&query=ablation&submit=Search \|title=''Glossary of Meteorology'' \|access-date=~~October~~2010-07-05 \|archive-url=https://web.archive.org/web/20110917232831/http://amsglossary.allenpress.com/glossary/search?p=1&query=ablation&submit=Search \|archive-date=2011-09-17 \|url-status=dead ~~2021~~}}</ref> ===Naphthalene=== [[File:Sublimation reaction of naphthalene.jpg\|thumb\|Experimental set up for the sublimation reaction of [[naphthalene]], ~~Solid~~solid naphthalene sublimes and form the crystal-like structure at the bottom of the [[watch glass]]]]▼ [[Naphthalene]], an organic compound commonly found in pesticides such as [[mothball]]s, sublimes easily because it is made of non-polar molecules that are held together only by [[Van der Waals force\|van der Waals]] intermolecular forces. Naphthalene is a solid that sublimes gradually at [[standard temperature and pressure]]<ref>▼ [[File:Crystal-like sublimated naphthalene.jpg\|thumb\|Solid compound of [[naphthalene]] sublimed to form a crystal-like structure on the cool surface.]]▼ ▲[[Naphthalene]], an organic compound commonly found in pesticides such as [[mothball]]s, sublimes easily because it is made of non-polar molecules that are held together only by [[Van der Waals force\|van der Waals]] intermolecular forces. Naphthalene is a solid that sublimes gradually at [[standard temperature and pressure]],<ref> {{cite book \|last=Caroll \|first=J. Line 79 ⟶ 83: \|isbn=9780128005750 \|page=16 \|publisher=Gulf Professional }}</ref>, at a high rate, with the critical sublimation point at around 80{{~~nbsp}}°~~convert\|80\|C ~~or 176{{nbsp~~\|F}}°F.<ref> {{cite web \|author=Staff writer(s) \|date=2015 \|title=what ~~solid~~solids go through sublimation? \|publisher=National Science Foundation and UCSB School-University partnership \|url=http://scienceline.ucsb.edu/getkey.php?key=4306 Line 94 ⟶ 99: \|isbn=978-0534408336 \|pages=781–782 \|publisher=Thomson Brooks/Cole }}</ref> to make the solid form of naphthalene evaporate into gas. On cool surfaces, the naphthalene vapours will solidify to form needle-like crystals. ▲[[File:Sublimation reaction of naphthalene.jpg\|thumb\|Experimental set up for the sublimation reaction of [[naphthalene]] Solid naphthalene sublimes and form the crystal-like structure at the bottom of the [[watch glass]]]] ▲[[File:Crystal-like sublimated naphthalene.jpg\|thumb\|Solid compound of [[naphthalene]] sublimed to form a crystal-like structure on the cool surface.]] ===Iodine=== [[Iodine]] ~~gradually~~ sublimes gradually and produces visible fumes on gentle heating at [[standard conditions for temperature and pressure\|standard atmospheric temperature]]. It is possible to obtain liquid iodine at atmospheric pressure by controlling the temperature at just between the melting point and the boiling point of iodine. In [[forensic science]], iodine vapor can reveal latent [[fingerprint]]s on paper.<ref>{{cite book▼ [[File:Camphor sublimation 1.jpg\|thumb\|upright\|[[Camphor]] subliming in a [[cold finger]]. The crude product in the bottom is dark brown; the white purified product on the bottom of the cold finger above is hard to see against the light background.]]▼ ▲[[Iodine]] gradually sublimes and produces visible fumes on gentle heating at [[standard conditions for temperature and pressure\|standard atmospheric temperature]]. It is possible to obtain liquid iodine at atmospheric pressure by controlling the temperature at just between the melting point and the boiling point of iodine. In [[forensic science]], iodine vapor can reveal latent [[fingerprint]]s on paper.<ref>{{cite book \|last=Girard \|first=James \|year= 2011 Line 112 ⟶ 113: === Other substances === ▲[[File:Camphor sublimation 1.jpg\|thumb\|upright\|[[Camphor]] subliming in a [[cold finger]]. The crude product in the bottom is dark brown; the white purified product on the bottom of the cold finger above is hard to see against the light background.]] ~~[[Arsenic]] can sublime readily at high temperatures.~~ At [[atmospheric pressure]], [[arsenic]] sublimes gradually upon heating, and sublimes rapidly at {{convert\|887\|K\|C}}.<ref name="Holl3">{{cite book \|last=Holleman \|first=Arnold F. \|title=Lehrbuch der Anorganischen Chemie \|author2=Wiberg, Egon \|author3=Wiberg, Nils \|date=1985 \|publisher=Walter de Gruyter \|isbn=978-3-11-007511-3 \|edition=91–100 \|pages=675–681 \|language=de \|chapter=Arsen}}</ref> [[Cadmium]] and [[zinc]] sublime much more than other common materials, so they are not suitable [[materials for use in vacuum]].{{citation needed\|date=May 2019}} Line 163 ⟶ 166: The result of the sublimation process is a nearly permanent, high resolution, full color print. Because the dyes are infused into the substrate at the molecular level, rather than applied at a topical level (such as with screen printing and direct to garment printing), the prints will not crack, fade or peel from the substrate under normal conditions.{{citation needed\|date=October 2021}} ==Table of phase transitions of matter==▼ {{Table of phase transitions}}▼ ==See also== Line 171 ⟶ 177: [[Phase diagram]] [[Phase transition\|Phase transitions]] ▲==Table of phase transitions of matter== ▲{{Table of phase transitions}} ~~{{Clear}}~~ ==References==