Phosphorus pentachloride: Difference between revisions

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			{{Redirect\|PCl5\|the printer protocol\|Printer Command Language}}
	{{chembox
			{{Chembox
			\| Verifiedfields = changed
	\| Watchedfields = changed		\| Watchedfields = changed
	\| verifiedrevid = ~~415592234~~		\| verifiedrevid = 455252348
	\| Name = Phosphorus pentachloride		\| Name = Phosphorus pentachloride
	\| ImageFile = Phosphorus-pentachloride-2D-dimensions.png		\| ImageFile = Phosphorus-pentachloride-2D-dimensions.png
	\| ImageSize =		\| ImageSize = 100px
	\| ImageName = Phosphorus pentachloride (gas phase structure)		\| ImageName = Phosphorus pentachloride (gas phase structure)
	\| ~~ImageFile1~~ = Phosphorus-pentachloride-3D-balls.png		\| ImageFileL1 = Phosphorus-pentachloride-3D-balls.png
	\| ~~ImageSize1~~ =		\| ImageSizeL1 = 100px
	\| ~~ImageName1~~ = Phosphorus pentachloride		\| ImageNameL1 = Phosphorus pentachloride
	\| ~~ImageFile2~~ = Phosphorus pentachloride ~~ampoule~~.~~jpg~~		\| ImageFileR1 = Phosphorus-pentachloride-3D-vdW.png
			\| ImageSizeR1 = 100px
	\| IUPACName = Phosphorus pentachloride<br />Phosphorus(V) chloride
			\| ImageFile2 = Phosphorus pentachloride ampoule.jpg
	\| OtherNames = Pentachlorophosphorane
			\| IUPACName = Phosphorus pentachloride<br> Pentachloro-λ<sup>5</sup>-phosphane
	\| Section1 = {{Chembox Identifiers
			\| OtherNames = Pentachlorophosphorane
	\| SMILES = ClP(Cl)(Cl)(Cl)Cl
			\|Section1={{Chembox Identifiers
	\| CASNo = 10026-13-8
			\| SMILES = ClP(Cl)(Cl)(Cl)Cl
	\| CASNo_Ref = {{cascite\|correct\|CAS}}
			\| ChemSpiderID_Ref = {{chemspidercite\|changed\|chemspider}}
	\| PubChem = 24819
			\| ChemSpiderID = 23204
	\| EINECS = 233-060-3
			\| InChI = 1/Cl5P/c1-6(2,3,4)5
	\| RTECS = TB6125000
			\| InChIKey = UHZYTMXLRWXGPK-UHFFFAOYAP
	\| UNNumber = 1806
			\| StdInChI_Ref = {{stdinchicite\|changed\|chemspider}}
	}}
			\| StdInChI = 1S/Cl5P/c1-6(2,3,4)5
	\| Section2 = {{Chembox Properties
			\| StdInChIKey_Ref = {{stdinchicite\|changed\|chemspider}}
	\| Formula = PCl<sub>5</sub>
			\| StdInChIKey = UHZYTMXLRWXGPK-UHFFFAOYSA-N
	\| MolarMass = 208.24 g/mol
			\| CASNo = 10026-13-8
	\| Appearance = colourless crystals
			\| CASNo_Ref = {{cascite\|correct\|CAS}}
	\| Density = 2.1 g/cm<sup>3</sup>
			\| UNII_Ref = <!-- {{fdite\|correct\|FDA}} no such template:fdite-->
	\| Solubility = decomposition (exothermic)
			\| UNII = 0EX753TYDU
	\| SolubleOther = soluble in ], ], ]
			\| PubChem = 24819
	\| MeltingPt = 166.8 °C, 440.0 K, 332.2 °F
			\| EINECS = 233-060-3
	\| BoilingPtC = 160
			\| RTECS = TB6125000
	\| Boiling_notes = sublimation
			\| UNNumber = 1806
	}}
			}}
	\| Section3 = {{Chembox Structure
			\|Section2={{Chembox Properties
	\| Coordination = trigonal bipyramidal
			\| P=1 \| Cl=5
	\| CrystalStruct = tetragonal
			\| Appearance = yellowish white crystals
	\| Dipole = 0 ]
			\| Odor = pungent, unpleasant<ref name=PGCH/>
	\| Coordination = D<sub>3h</sub>
			\| Density = 2.1 g/cm<sup>3</sup>
	}}
			\| Solubility = reacts
	\| Section7 = {{Chembox Hazards
			\| SolubleOther = soluble in ], ], ]
	\| ExternalMSDS =
			\| MeltingPtC = 160.5
	\| EUIndex = 015-008-00-X
			\| BoilingPtC = 166.8
	\| EUClass = Very toxic ('''T+''')
			\| BoilingPt_notes = sublimation
	\| RPhrases = {{R14}}, {{R22}}, {{R26}}, {{R34}}, {{R48/20}}
			\| VaporPressure = 1.11 kPa (80 °C)<br> 4.58 kPa (100 °C)<ref name=nist>{{nist\|name=Phosphorus pentachloride\|id=C10026138\|accessdate=2014-05-15\|mask=FFFF\|units=SI}}</ref>
	\| SPhrases = {{S1/2}}, {{S7/8}}, {{S26}}, {{S36/37/39}}, {{S45}}
			}}
	\| NFPA-H = 3
			\|Section3={{Chembox Structure
	\| NFPA-F = 0
			\| Coordination = ''D''<sub>3h</sub> (])
	\| NFPA-R = 2
			\| CrystalStruct = tetragonal
	\| NFPA-O = W
			\| Dipole = 0 ]
	\| FlashPt = Non-flammable
			}}
	\| LD50 = 660 mg/kg
			\|Section4={{Chembox Thermochemistry
	}}
			\| HeatCapacity = 111.5 J/mol·K<ref name=nist />
	\| Section8 = {{Chembox Related
			\| Entropy = 364.2 J/mol·K<ref name=nist />
	\| OtherAnions =
	\| ~~OtherCations~~ =		\| DeltaHf =
			\| DeltaGf =
	\| OtherFunctn = ]<br />]<br />]
			\| DeltaHc =
	\| Function = phosphorus pentahalides
			}}
	\| OtherCpds = ]<br />]
			\|Section7={{Chembox Hazards
	}}
			\| GHSPictograms = {{GHS05}}{{GHS06}}{{GHS08}}<ref name="sigma"></ref>
			\| GHSSignalWord = Danger
			\| HPhrases = {{H-phrases\|302\|314\|330\|373}}<ref name="sigma" />
			\| PPhrases = {{P-phrases\|260\|280\|284\|305+351+338\|310}}<ref name="sigma" />
			\| ExternalSDS =
			\| NFPA-H = 3
			\| NFPA-F = 0
			\| NFPA-R = 2
			\| NFPA-S = W
			\| FlashPt = Non-flammable
			\| LD50 = 660 mg/kg (rat, oral)<ref name=IDLH/>
			\| IDLH = 70 mg/m<sup>3</sup><ref name=PGCH>{{PGCH\|0509}}</ref>
			\| LC50 = 205 mg/m<sup>3</sup> (rat)<ref name=IDLH>{{IDLH\|10026138\|Phosphorus pentachloride}}</ref>
			\| REL = TWA 1 mg/m<sup>3</sup><ref name=PGCH/>
			\| PEL = TWA 1 mg/m<sup>3</sup><ref name=PGCH/>
			\| LCLo = 1020 mg/m<sup>3</sup> (mouse, 10 min)<ref name=IDLH/>
			}}
			\|Section8={{Chembox Related
			\| OtherAnions =
			\| OtherCations =
			\| OtherFunction = ]<br />]<br />]
			\| OtherFunction_label = phosphorus pentahalides
			\| OtherCompounds = ]<br />]
			}}
	}}		}}
	'''Phosphorus pentachloride''' is the ] with the formula PCl<sub>5</sub>. It is one of the most important phosphorus chlorides, others being ] and ]. PCl<sub>5</sub> finds use as a ~~chlorinating~~ ]. It is a colourless, water-sensitive ], although commercial samples can be yellowish and contaminated with ].		'''Phosphorus pentachloride''' is the ] with the formula PCl<sub>5</sub>. It is one of the most important ] chlorides/oxychlorides, others being ] and ]. PCl<sub>5</sub> finds use as a ] reagent. It is a colourless, water-sensitive ], although commercial samples can be yellowish and contaminated with ].

	==Structure==		==Structure==
	The structures for the phosphorus chlorides are invariably consistent with ] theory. The structure of PCl<sub>5</sub> depends on its environment. Gaseous and molten PCl<sub>5</sub> is a neutral molecule with trigonal bipyramidal (''D''<sub>3h</sub>) ]. The ] nature of this species (as well as ~~for~~ ~~PCl~~{{su\|b=6\|~~p=−~~}}, see below) can be explained with ]~~ing~~ ~~model~~. This trigonal bipyramidal structure persists in ~~non-polar~~ solvents, such as ] and ].<ref>D. E. C. Corbridge "Phosphorus: An ~~Outline~~ of its ~~Chemistry~~, ~~Biochemistry~~, and ~~Technology"~~ ~~5th~~ ~~Edition~~ Elsevier: ~~Amsterdam~~ ~~1995.~~ ~~ISBN~~ 0-444-89307-5.</ref> In the solid state PCl<sub>5</sub> is ionic, formulated ~~PCl~~{{su\|b=4\|p=+}}PCl~~{{su~~\|b=6\|~~p=−~~}}.<ref name="Holleman">~~Holleman,~~ A. F.~~; Wiberg,~~ E. "Inorganic Chemistry" ~~Academic~~ ~~Press:~~ ~~San~~ ~~Diego,~~ ~~2001.~~ ~~ISBN~~ 0-12-352651-5.</ref>		The structures for the phosphorus chlorides are invariably consistent with ]. The structure of PCl<sub>5</sub> depends on its environment. Gaseous and molten PCl<sub>5</sub> is a neutral molecule with ] geometry and (''D''<sub>3h</sub>) ]. The ] nature of this species (as well as of {{chem\|PCl\|6\|-}}, see below) can be explained with the inclusion of non-bonding ]s (]) or ] (]). This trigonal bipyramidal structure persists in nonpolar solvents, such as ] and ].<ref>{{cite book\| first = D. E. C. \| last=Corbridge\| title = Phosphorus: An outline of its chemistry, biochemistry, and uses\| year = 1995\| publisher = Elsevier Science \| isbn = 0-444-89307-5 }}</ref> In the solid state PCl<sub>5</sub> is an ] called tetrachlorophosphonium hexachlorophosphate formulated {{chem\|PCl\|4\|+\|PCl\|6\|-}}.<ref name="Holleman">{{cite book\| first1= A. F.\|last1= Holleman\|first2=E.\|last2= Wiber \|first3=N.\|last3= Wiberg \| title = Inorganic Chemistry\| year = 2001\| publisher = Academic Press\| isbn = 978-0-12-352651-9 }}</ref>

			]
	In solutions of polar solvents, PCl<sub>5</sub> undergoes "autoionization".<ref>{{cite journal \| author = Suter, R. W.; Knachel, H. C.; Petro, V. P.; Howatson, J. H.; S. G. Shore, S. G. \| title = Nature of Phosphorus(V) Chloride in Ionizing and Nonionizing Solvents \| journal = ] \| volume = 95 \| year = 1973 \| pages = 1474–1479 \| doi = 10.1021/ja00786a021}}</ref> Dilute solutions dissociate according to the following equilibrium:

			In solutions of polar solvents, PCl<sub>5</sub> undergoes self-].<ref>{{cite journal \| last1= Suter \|first1=R. W.\|last2= Knachel \|first2=H. C. \|last3=Petro \|first3=V. P. \|last4=Howatson \|first4=J. H. \|last5= Shore\|first5= S. G. \|name-list-style=amp \| title = Nature of Phosphorus(V) Chloride in Ionizing and Nonionizing Solvents \| journal = ] \| volume = 95 \| year = 1978 \| pages = 1474–1479 \| doi = 10.1021/ja00786a021 \| issue = 5}}</ref> Dilute solutions dissociate according to the following equilibrium:
	:PCl<sub>5</sub> {{eqm}} Cl<sup>−</sup>

			:PCl<sub>5</sub> {{eqm}} {{chem\|PCl\|4\|+}} + Cl<sup>−</sup>
	At higher concentrations, a second equilibrium becomes more important:

			At higher concentrations, a second equilibrium becomes more prevalent:
	:2 PCl<sub>5</sub> {{eqm}}

			:2 PCl<sub>5</sub> {{eqm}} {{chem\|PCl\|4\|+}} + {{chem\|PCl\|6\|-}}
	The cation PCl{{su\|b=4\|p=+}} and the anion PCl{{su\|b=6\|p=−}} are tetrahedral and octahedral, respectively. At one time, PCl<sub>5</sub> in solution was thought to form a dimeric structure, P<sub>2</sub>Cl<sub>10</sub>, but this suggestion is not supported by ] measurements.

			The cation {{chem\|PCl\|4\|+}} and the anion {{chem\|PCl\|6\|-}} are ] and ], respectively. At one time, PCl<sub>5</sub> in solution was thought to form a dimeric structure, P<sub>2</sub>Cl<sub>10</sub>, but this suggestion is not supported by ] measurements.
	] and ] also adopt trigonal bipyramidal structures. The relevant bond distances are 211 (As-Cl<sub>eq</sub>), 221 (As-Cl<sub>eq</sub>), 227 (Sb-Cl<sub>eq</sub>), and 233.3 pm (Sb-Cl<sub>ax</sub> ).<ref>{{cite journal \| author = Haupt, S.; Seppelt, K. \| title = Solid State Structures of AsCl<sub>5</sub> and SbCl<sub>5</sub> \| journal = ] \| year = 2002 \| volume = 628 \|pages = 729–734 \| doi = 10.1002/1521-3749(200205)628:4<729::AID-ZAAC729>3.0.CO;2-E}}</ref> At low temperatures, SbCl<sub>5</sub> converts to the dimer, bioctahedral Sb<sub>2</sub>Cl<sub>10</sub>, structurally related to ].

			===Related pentachlorides===
			] and ] also adopt trigonal bipyramidal structures. The relevant bond distances are 211 pm (As−Cl<sub>eq</sub>), 221 pm (As−Cl<sub>ax</sub>), 227 pm (Sb−Cl<sub>eq</sub>), and 233.3 pm (Sb−Cl<sub>ax</sub>).<ref>{{cite journal \|last1=Haupt \|first1=S. \|last2=Seppelt \|first2=K. \| title = Solid State Structures of AsCl<sub>5</sub> and SbCl<sub>5</sub> \| journal = ] \| year = 2002 \| volume = 628 \|pages = 729–734 \| doi = 10.1002/1521-3749(200205)628:4<729::AID-ZAAC729>3.0.CO;2-E \| issue = 4\| doi-access = free }}</ref> At low temperatures, SbCl<sub>5</sub> converts to the dimer, dioctahedral Sb<sub>2</sub>Cl<sub>10</sub>, structurally related to ].

	==Preparation==		==Preparation==
	PCl<sub>5</sub> is prepared by the ] of PCl<sub>3</sub>. This reaction ~~was~~ used to produce ~~ca.~~ 10,000~~,000 kg~~ of PCl<sub>5</sub> in 2000.<ref name="Holleman" />		PCl<sub>5</sub> is prepared by the ] of PCl<sub>3</sub>.<ref>{{cite book\|first=R. N.\|last=Maxson\|chapter=Phosphorus Pentachloride\|date=1939\|volume=1\|pages=99–100\|doi=10.1002/9780470132326.ch34\|title=Inorganic Syntheses\|isbn=9780470132326}}</ref> This reaction is used to produce around 10,000 tonnes of PCl<sub>5</sub> per year (as of 2000).<ref name="Holleman" />
	:PCl<sub>3</sub> + Cl<sub>2</sub> {{eqm}} PCl<sub>5</sub> (~~Δ~~H = −124 kJ/mol)		:PCl<sub>3</sub> + Cl<sub>2</sub> {{eqm}} PCl<sub>5</sub> {{pad\|3em}} (Δ''H'' = −124 kJ/mol)

	PCl<sub>5</sub> exists in equilibrium with PCl<sub>3</sub> and ], and at 180 °C the degree of dissociation is ~~ca.~~ 40%.<ref name="Holleman" /> Because of this equilibrium, samples of PCl<sub>5</sub> often contain chlorine, which imparts a greenish ~~colouration~~.		PCl<sub>5</sub> exists in equilibrium with PCl<sub>3</sub> and ], and at 180 °C the degree of dissociation is about 40%.<ref name="Holleman" /> Because of this equilibrium, samples of PCl<sub>5</sub> often contain chlorine, which imparts a greenish coloration.

	==Reactions==		==Reactions==

	===Hydrolysis===		===Hydrolysis===
	In its most characteristic reaction, PCl<sub>5</sub> ] upon contact with ] to release ] and give phosphorus oxides.		In its most characteristic reaction, PCl<sub>5</sub> ] upon contact with ] to release ] and give phosphorus oxides. The first hydrolysis product is ]:
			:PCl<sub>5</sub> + H<sub>2</sub>O → POCl<sub>3</sub> + 2 HCl
	The first hydrolysis product is ]:
	:PCl<sub>5</sub> + H<sub>2</sub>O → POCl<sub>3</sub> + 2 HCl

	In hot water, hydrolysis proceeds completely to ~~''ortho''-~~]:		In hot water, hydrolysis proceeds completely to ]:
	:PCl<sub>5</sub> + 4 H<sub>2</sub>O → H<sub>3</sub>PO<sub>4</sub> + 5 HCl~~</center>~~		:PCl<sub>5</sub> + 4 H<sub>2</sub>O → H<sub>3</sub>PO<sub>4</sub> + 5 HCl

			===Lewis acidity===
	PCl<sub>5</sub> is most often used for chlorinations of organic and inorganic compounds.<ref name="Burks">Burks, Jr., J. E. “Phosphorus(V) Chloride” in Encyclopedia of Reagents for Organic Synthesis (Ed: L. Paquette) 2004, J. Wiley & Sons, New York. DOI: 10.1002/047084289.</ref>
			Phosphorus pentachloride is a Lewis acid. This property underpins many of its characteristic reactions, autoionization, chlorinations, hydrolysis. A well studied adduct is PCl<sub>5</sub>(pyridine).<ref>{{cite journal\|title=Neutral Six-Coordinate Phosphorus\|first1=Chih Y.\|last1=Wong\|first2=Dietmar K.\|last2=Kennepohl\|first3=Ronald G.\|last3=Cavell\|journal=Chemical Reviews\|year=1996\|volume=96\|issue=6\|pages=1917–1952\|doi=10.1021/cr9410880\|pmid=11848816}}</ref>

	===Chlorination of organic compounds===		===Chlorination of organic compounds===
	In synthetic chemistry, two classes of chlorination are usually of interest. Oxidative chlorinations entail the transfer of Cl<sub>2</sub> from the reagent to the substrate. Substitutive chlorinations entail replacement of O or OH groups with chloride. PCl<sub>5</sub> can be used for both processes.		In synthetic chemistry, two classes of chlorination are usually of interest: oxidative chlorinations and substitutive chlorinations. Oxidative chlorinations entail the transfer of Cl<sub>2</sub> from the reagent to the substrate. Substitutive chlorinations entail replacement of O or OH groups with chloride. PCl<sub>5</sub> can be used for both processes.

	PCl<sub>5</sub> ~~will convert~~ ]s to the corresponding ]<ref>{{OrgSynth \| ~~author~~ = ], R.; Jenkins, R. L. \| title = ''p''-Nitrobenzoyl chloride \| collvol = 1 \| collvolpages = 394 \| prep = cv1p0394 \| year = 1941}}</ref> as ~~well~~ as ]s to ]. ~~] is more commonly used in the laboratory because the SO<sub>2<~~/~~sub> is more easily separated from the organic products than is POCl<sub>3~~</~~sub~~>.		Upon treatment with PCl<sub>5</sub>, ]s convert to the corresponding ].<ref>{{OrgSynth \| authorlink = Roger Adams\|last1=Adams \|first1=R. \|last2=Jenkins \|first2=R. L. \| title = ''p''-Nitrobenzoyl chloride \| collvol = 1 \| collvolpages = 394 \| prep = cv1p0394 \| year = 1941}}</ref> The following mechanism has been proposed:<ref>{{cite book\|last=Clayden\|first=Jonathan\|title=Organic chemistry\|year=2005\|publisher=Oxford University Press\|location=Oxford\|isbn=978-0-19-850346-0\|edition=Reprinted\|url-access=registration\|url=https://archive.org/details/organicchemistry00clay_0}}</ref>
			:]

			It also converts ]s to ]. ] is more commonly used in the laboratory because the resultant ] is more easily separated from the organic products than is POCl<sub>3</sub>.
	PCl<sub>5</sub> and PCl<sub>3</sub> bear some resemblance to ], as both serve often as sources of Cl<sub>2</sub>. Again for oxidative chlorinations on the laboratory scale, ] is often preferred over PCl<sub>5</sub> since the gaseous SO<sub>2</sub> by-product is readily separated.

	PCl<sub>5</sub> reacts with a tertiary amides, such as ], to give dimethylchloromethyleneammonium chloride, which is called the ], Cl. More typically, a related salt is generated from the reaction of DMF and POCl<sub>3</sub>. Such reagents are useful in the preparation of derivatives of ] by formylation and for the conversion of ~~C-OH~~ groups into ~~C-Cl~~ groups.<ref name="Burks" />		PCl<sub>5</sub> reacts with a tertiary amides, such as ] (DMF), to give dimethylchloromethyleneammonium chloride, which is called the ], Cl. More typically, a related salt is generated from the reaction of DMF and POCl<sub>3</sub>. Such reagents are useful in the preparation of derivatives of ] by formylation and for the conversion of C−OH groups into C−Cl groups.<ref name="Burks">{{cite encyclopedia\|last=Burks Jr. \|first=J. E. \|title=Encyclopedia of Reagents for Organic Synthesis \|chapter=Phosphorus(V) chloride \|editor-first=L. \|editor-last=Paquette \|date=2004 \|publisher=J. Wiley & Sons \|location=New York, NY \|doi=10.1002/047084289X.rp158\|isbn=0471936235 }}</ref>

	~~In contrast to PCl<sub>3</sub>, the pentachloride replaces allylic and benzylic CH bonds and~~ is especially renowned for the conversion of C=O groups to CCl<sub>2</sub> groups.<ref>{{OrgSynth \| ~~author~~ = Gross, H.; Rieche, A.; Höft, E.; Beyer, E. \| title = Dichloromethyl ~~Methyl~~ ~~Ether~~ \| collvol = 5 \| collvolpages = 365 \| prep = cv5p0365 \| year = 1973}}</ref>		It is especially renowned for the conversion of ] groups to CCl<sub>2</sub> groups.<ref>{{OrgSynth \| last1= Gross \|first1=H. \|last2=Rieche \|first2=A. \|last3=Höft \|first3=E. \|last4=Beyer \|first4=E. \| title = Dichloromethyl methyl ether \| collvol = 5 \| collvolpages = 365 \| prep = cv5p0365 \| year = 1973}}</ref> For example, ] and phosphorus pentachloride react to give the ]:<ref name="Spaggiari2007">{{cite journal\|last1=Spaggiari\|first1=A.\|first2=D. \|last2=Vaccari \|first3=P. \|last3=Davoli \|first4=G. \|last4=Torre \|first5=F. \|last5=Prati \|year=2007\|title=A Mild Synthesis of Vinyl Halides and ''gem''-Dihalides Using Triphenyl Phosphite−Halogen-Based Reagents\|journal=The Journal of Organic Chemistry\|volume=72\|issue=6\|pages=2216–2219\|issn=0022-3263\|pmid=17295542\|doi=10.1021/jo061346g}}</ref>
			:(C<sub>6</sub>H<sub>5</sub>)<sub>2</sub>CO + PCl<sub>5</sub> → (C<sub>6</sub>H<sub>5</sub>)<sub>2</sub>CCl<sub>2</sub> + POCl<sub>3</sub>

	The ] character of PCl<sub>5</sub> is highlighted by its reaction with ] to give, after ], phosphonic acid derivatives.<ref>{{OrgSynth \| ~~author~~ = Schmutzler, R. \| title = Styrylphosphonic dichloride \| collvol = 5 \| collvolpages = 1005 \| prep = cv5p1005 \| year = 1973}}</ref>		The ] character of PCl<sub>5</sub> is highlighted by its reaction with ] to give, after ], ] derivatives.<ref>{{OrgSynth \| last= Schmutzler \|first=R. \| title = Styrylphosphonic dichloride \| collvol = 5 \| collvolpages = 1005 \| prep = cv5p1005 \| year = 1973}}</ref>

			===Comparison with related reagents===
			Both PCl<sub>3</sub> and PCl<sub>5</sub> convert R<sub>3</sub>COH groups to the chloride R<sub>3</sub>CCl. The pentachloride is however a source of chlorine in many reactions. It chlorinates allylic and ] CH bonds. PCl5 bears a greater resemblance to ], also a source of Cl<sub>2</sub>. For oxidative chlorinations on the laboratory scale, sulfuryl chloride is often preferred over PCl<sub>5</sub> since the gaseous SO<sub>2</sub> by-product is readily separated.

	===Chlorination of inorganic compounds===		===Chlorination of inorganic compounds===
	As for the reactions with organic compounds, the use of PCl<sub>5</sub> has been superseded by SO<sub>2</sub>Cl<sub>2</sub>. The reaction of ] and PCl<sub>5</sub> produces ]:<ref>F. A. ~~Cotton,~~ G. ~~Wilkinson,~~ C. A. ~~Murillo, and M. Bochmann (April 1999).~~ Advanced Inorganic Chemistry, ~~6th~~ ~~Edition.~~ Wiley-~~VCH.~~ ~~ISBN~~ 0-471-19957-5</ref>		As for the reactions with organic compounds, the use of PCl<sub>5</sub> has been superseded by SO<sub>2</sub>Cl<sub>2</sub>. The reaction of ] and PCl<sub>5</sub> produces ] :<ref>{{cite book\| first= Frank Albert\|last= Cotton\| title = Advanced Inorganic Chemistry\| year = 1999\| publisher = Wiley-Interscience\| isbn = 978-0-471-19957-1 }}</ref>{{page needed\|date=September 2017}}

	:6 PCl<sub>5</sub> + P<sub>4</sub>O<sub>10</sub> → 10 POCl<sub>3</sub~~></center~~>		:6 PCl<sub>5</sub> + P<sub>4</sub>O<sub>10</sub> → 10 POCl<sub>3</sub>

	PCl<sub>5</sub> chlorinates ] to form ] ~~chloride~~:		PCl<sub>5</sub> chlorinates ] to form unstable ]:

	:PCl<sub>5</sub> + 2 NO<sub>2</sub> → PCl<sub>3</sub> + 2 NO<sub>2</sub>Cl		:PCl<sub>5</sub> + 2 NO<sub>2</sub> → PCl<sub>3</sub> + 2 NO<sub>2</sub>Cl
			:2 NO<sub>2</sub>Cl → 2 NO<sub>2</sub> + Cl<sub>2</sub>

	PCl<sub>5</sub> is a precursor for ], LiPF<sub>6</sub>, an ] in ]. {{chem\|LiPF\|6}} is produced by the reaction of {{chem\|PCl\|5}} with ], with ] as a side-product:		PCl<sub>5</sub> is a precursor for ], LiPF<sub>6</sub>. Lithium hexafluorophosphate is a commonly employed salt in ]s in ].<ref name="Dobrov-2017">{{cite journal \|last1=Bushkova \|first1=O. V. \|last2=Yaroslavtseva \|first2=T. V. \|last3=Dobrovolsky \|first3=Yu. A. \|title=New lithium salts in electrolytes for lithium-ion batteries (Review) \|journal=Russian Journal of Electrochemistry \|date=4 August 2017 \|volume=53 \|issue=7 \|pages=677–699 \|doi=10.1134/S1023193517070035\|s2cid=103854243 }}</ref> {{chem\|LiPF\|6}} is produced by the reaction of {{chem\|PCl\|5}} with ], with ] as a side product:

	:PCl<sub>5</sub> + 6 LiF → LiPF<sub>6</sub> + 5 LiCl		:PCl<sub>5</sub> + 6 LiF → LiPF<sub>6</sub> + 5 LiCl

	==Safety==		==Safety==
	PCl<sub>5</sub> is a dangerous substance as it reacts violently with water.		PCl<sub>5</sub> is a dangerous substance as it reacts violently with water. It is also corrosive when in contact with skin and can be fatal when inhaled.

			== History ==

			Phosphorus pentachloride was first prepared in 1808 by the English chemist ].<ref>{{cite journal\|last1=Davy\|first1=Humphry\|title=The Bakerian Lecture. An account of some new analytical researches on the nature of certain bodies, particularly the alkalies, phosphorus, sulphur, carbonaceous matter, and the acids hitherto undecomposed; with some general observations on chemical theory\|journal=Philosophical Transactions of the Royal Society of London\|date=1809\|volume=99\|pages=39–104\|url=https://babel.hathitrust.org/cgi/pt?id=mdp.39015034564347;view=1up;seq=53\|doi=10.1098/rstl.1809.0005\|s2cid=98814859}} On pp. 94–95, Davy mentioned that when he burned phosphorus in chlorine gas ("oxymuriatic acid gas"), he obtained a clear liquid (phosphorus trichloride) and a white solid (phosphorus pentachloride).</ref> Davy's analysis of phosphorus pentachloride was inaccurate;<ref>{{cite journal\|last1=Davy\|first1=Humphry\|title=Researches on the oxymuriatic acid , its nature and combinations; and on the elements of the muriatic acid . With some experiments on sulphur and phosphorus, made in the laboratory of the Royal Institution\|journal=Philosophical Transactions of the Royal Society of London\|date=1810\|volume=100\|pages=231–257\|url=https://babel.hathitrust.org/cgi/pt?id=mdp.39015034564339;view=1up;seq=301\|doi=10.1098/rstl.1810.0016\|doi-access=\|s2cid=95219058 }} On p. 257, Davy presented his empirical formula for phosphorus pentachloride: 1 portion of phosphorus to 3 portions of "oxymuriatic gas" (chlorine).</ref> the first accurate analysis was provided in 1816 by the French chemist ].<ref>{{cite journal\|last1=Dulong\|title=Extrait d'un mémoire sur les combinaisons du phosphore avec l'oxigène\|journal=Annales de Chimie et de Physique\|date=1816\|volume=2\|pages=141–150\|url=https://babel.hathitrust.org/cgi/pt?id=hvd.hx3dvb;view=1up;seq=147\|series=2nd series\|trans-title=Extract from a memoir on the compounds of phosphorus with oxygen\|language=fr}} On p. 148, Dulong presented the correct analysis of phosphorus pentachloride (which is 14.9% phosphorus and 85.1% chlorine by weight, vs. Dulong's values of 15.4% and 84.6%, respectively).</ref>

	==See also==		==See also==
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	==References==		==References==
	{{~~reflist~~}}		{{Reflist\|30em}}

	==External links==		==External links==
			{{Commons category\|Phosphorus pentachloride}}
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	{{Phosphorus compounds}}		{{Phosphorus compounds}}
			{{Chlorides}}
			{{Authority control}}

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Latest revision as of 08:25, 2 October 2024

"PCl5" redirects here. For the printer protocol, see Printer Command Language.

Phosphorus pentachloride

Names

IUPAC names Phosphorus pentachloride
Pentachloro-λ-phosphane

Other names Pentachlorophosphorane

Identifiers

CAS Number

10026-13-8

3D model (JSmol)

Interactive image

ChemSpider

23204

ECHA InfoCard

100.030.043

EC Number

233-060-3

PubChem CID

24819

RTECS number

TB6125000

UNII

0EX753TYDU

UN number

1806

CompTox Dashboard (EPA)

DTXSID9033896

InChI

InChI=1S/Cl5P/c1-6(2,3,4)5Key: UHZYTMXLRWXGPK-UHFFFAOYSA-N
InChI=1/Cl5P/c1-6(2,3,4)5Key: UHZYTMXLRWXGPK-UHFFFAOYAP

SMILES

ClP(Cl)(Cl)(Cl)Cl

Properties

Chemical formula

Cl₅P

Molar mass

208.22 g·mol

Appearance

yellowish white crystals

Odor

pungent, unpleasant

Density

2.1 g/cm

Melting point

160.5 °C (320.9 °F; 433.6 K)

Boiling point

166.8 °C (332.2 °F; 439.9 K) sublimation

Solubility in water

reacts

Solubility

soluble in CS₂, chlorocarbons, benzene

Vapor pressure

1.11 kPa (80 °C)
4.58 kPa (100 °C)

Structure

Crystal structure

tetragonal

Coordination geometry

D_3h (trigonal bipyramidal)

Dipole moment

0 D

Thermochemistry

Heat capacity (C)

111.5 J/mol·K

Std molar
entropy (S₂₉₈)

364.2 J/mol·K

Hazards

GHS labelling:

Pictograms

Signal word

Danger

Hazard statements

H302, H314, H330, H373

Precautionary statements

P260, P280, P284, P305+P351+P338, P310

NFPA 704 (fire diamond)

3 0 2 W

Flash point

Non-flammable

Lethal dose or concentration (LD, LC):

LD₅₀ (median dose)

660 mg/kg (rat, oral)

LC₅₀ (median concentration)

205 mg/m (rat)

LC_Lo (lowest published)

1020 mg/m (mouse, 10 min)

NIOSH (US health exposure limits):

PEL (Permissible)

TWA 1 mg/m

REL (Recommended)

TWA 1 mg/m

IDLH (Immediate danger)

70 mg/m

Safety data sheet (SDS)

ICSC 0544

Related compounds

Related phosphorus pentahalides

Phosphorus pentafluoride
Phosphorus pentabromide
Phosphorus pentaiodide

Related compounds

Phosphorus trichloride
Phosphoryl chloride

Except where otherwise noted, data are given for materials in their standard state (at 25 °C , 100 kPa).

N verify (what is ?) Infobox references

Chemical compound

Phosphorus pentachloride is the chemical compound with the formula PCl₅. It is one of the most important phosphorus chlorides/oxychlorides, others being PCl₃ and POCl₃. PCl₅ finds use as a chlorinating reagent. It is a colourless, water-sensitive solid, although commercial samples can be yellowish and contaminated with hydrogen chloride.

Structure

The structures for the phosphorus chlorides are invariably consistent with VSEPR theory. The structure of PCl₅ depends on its environment. Gaseous and molten PCl₅ is a neutral molecule with trigonal bipyramidal geometry and (D_3h) symmetry. The hypervalent nature of this species (as well as of PCl
₆, see below) can be explained with the inclusion of non-bonding molecular orbitals (molecular orbital theory) or resonance (valence bond theory). This trigonal bipyramidal structure persists in nonpolar solvents, such as CS₂ and CCl₄. In the solid state PCl₅ is an ionic compound called tetrachlorophosphonium hexachlorophosphate formulated PCl
₄PCl
₆.

In solutions of polar solvents, PCl₅ undergoes self-ionization. Dilute solutions dissociate according to the following equilibrium:

PCl₅ ⇌ PCl
₄ + Cl

At higher concentrations, a second equilibrium becomes more prevalent:

2 PCl₅ ⇌ PCl
₄ + PCl
₆

The cation PCl
₄ and the anion PCl
₆ are tetrahedral and octahedral, respectively. At one time, PCl₅ in solution was thought to form a dimeric structure, P₂Cl₁₀, but this suggestion is not supported by Raman spectroscopic measurements.

Related pentachlorides

AsCl₅ and SbCl₅ also adopt trigonal bipyramidal structures. The relevant bond distances are 211 pm (As−Cl_eq), 221 pm (As−Cl_ax), 227 pm (Sb−Cl_eq), and 233.3 pm (Sb−Cl_ax). At low temperatures, SbCl₅ converts to the dimer, dioctahedral Sb₂Cl₁₀, structurally related to niobium pentachloride.

Preparation

PCl₅ is prepared by the chlorination of PCl₃. This reaction is used to produce around 10,000 tonnes of PCl₅ per year (as of 2000).

PCl₃ + Cl₂ ⇌ PCl₅ (ΔH = −124 kJ/mol)

PCl₅ exists in equilibrium with PCl₃ and chlorine, and at 180 °C the degree of dissociation is about 40%. Because of this equilibrium, samples of PCl₅ often contain chlorine, which imparts a greenish coloration.

Reactions

Hydrolysis

In its most characteristic reaction, PCl₅ reacts upon contact with water to release hydrogen chloride and give phosphorus oxides. The first hydrolysis product is phosphorus oxychloride:

PCl₅ + H₂O → POCl₃ + 2 HCl

In hot water, hydrolysis proceeds completely to orthophosphoric acid:

PCl₅ + 4 H₂O → H₃PO₄ + 5 HCl

Lewis acidity

Phosphorus pentachloride is a Lewis acid. This property underpins many of its characteristic reactions, autoionization, chlorinations, hydrolysis. A well studied adduct is PCl₅(pyridine).

Chlorination of organic compounds

In synthetic chemistry, two classes of chlorination are usually of interest: oxidative chlorinations and substitutive chlorinations. Oxidative chlorinations entail the transfer of Cl₂ from the reagent to the substrate. Substitutive chlorinations entail replacement of O or OH groups with chloride. PCl₅ can be used for both processes.

Upon treatment with PCl₅, carboxylic acids convert to the corresponding acyl chloride. The following mechanism has been proposed:

It also converts alcohols to alkyl chlorides. Thionyl chloride is more commonly used in the laboratory because the resultant sulfur dioxide is more easily separated from the organic products than is POCl₃.

PCl₅ reacts with a tertiary amides, such as dimethylformamide (DMF), to give dimethylchloromethyleneammonium chloride, which is called the Vilsmeier reagent, Cl. More typically, a related salt is generated from the reaction of DMF and POCl₃. Such reagents are useful in the preparation of derivatives of benzaldehyde by formylation and for the conversion of C−OH groups into C−Cl groups.

It is especially renowned for the conversion of C=O groups to CCl₂ groups. For example, benzophenone and phosphorus pentachloride react to give the diphenyldichloromethane:

(C₆H₅)₂CO + PCl₅ → (C₆H₅)₂CCl₂ + POCl₃

The electrophilic character of PCl₅ is highlighted by its reaction with styrene to give, after hydrolysis, phosphonic acid derivatives.

Comparison with related reagents

Both PCl₃ and PCl₅ convert R₃COH groups to the chloride R₃CCl. The pentachloride is however a source of chlorine in many reactions. It chlorinates allylic and benzylic CH bonds. PCl5 bears a greater resemblance to SO₂Cl₂, also a source of Cl₂. For oxidative chlorinations on the laboratory scale, sulfuryl chloride is often preferred over PCl₅ since the gaseous SO₂ by-product is readily separated.

Chlorination of inorganic compounds

As for the reactions with organic compounds, the use of PCl₅ has been superseded by SO₂Cl₂. The reaction of phosphorus pentoxide and PCl₅ produces POCl₃ :

6 PCl₅ + P₄O₁₀ → 10 POCl₃

PCl₅ chlorinates nitrogen dioxide to form unstable nitryl chloride:

PCl₅ + 2 NO₂ → PCl₃ + 2 NO₂Cl

2 NO₂Cl → 2 NO₂ + Cl₂

PCl₅ is a precursor for lithium hexafluorophosphate, LiPF₆. Lithium hexafluorophosphate is a commonly employed salt in electrolytes in lithium ion batteries. LiPF
₆ is produced by the reaction of PCl
₅ with lithium fluoride, with lithium chloride as a side product:

PCl₅ + 6 LiF → LiPF₆ + 5 LiCl

Safety

PCl₅ is a dangerous substance as it reacts violently with water. It is also corrosive when in contact with skin and can be fatal when inhaled.

History

Phosphorus pentachloride was first prepared in 1808 by the English chemist Humphry Davy. Davy's analysis of phosphorus pentachloride was inaccurate; the first accurate analysis was provided in 1816 by the French chemist Pierre Louis Dulong.

References

^ NIOSH Pocket Guide to Chemical Hazards. "#0509". National Institute for Occupational Safety and Health (NIOSH).
^ Phosphorus pentachloride in Linstrom, Peter J.; Mallard, William G. (eds.); NIST Chemistry WebBook, NIST Standard Reference Database Number 69, National Institute of Standards and Technology, Gaithersburg (MD) (retrieved 2014-05-15)
^ Phosphorus pentachloride
^ "Phosphorus pentachloride". Immediately Dangerous to Life or Health Concentrations (IDLH). National Institute for Occupational Safety and Health (NIOSH).
Corbridge, D. E. C. (1995). Phosphorus: An outline of its chemistry, biochemistry, and uses. Elsevier Science. ISBN 0-444-89307-5.
^ Holleman, A. F.; Wiber, E.; Wiberg, N. (2001). Inorganic Chemistry. Academic Press. ISBN 978-0-12-352651-9.
Finch, A.; Fitch, A.N.; Gates, P.N. (1993). "Crystal and Molecular structure of a metastable modification of phosphorus pentachloride". Journal of the Chemical Society, Chemical Communications (11): 957–958. doi:10.1039/C39930000957.
Suter, R. W.; Knachel, H. C.; Petro, V. P.; Howatson, J. H. & Shore, S. G. (1978). "Nature of Phosphorus(V) Chloride in Ionizing and Nonionizing Solvents". Journal of the American Chemical Society. 95 (5): 1474–1479. doi:10.1021/ja00786a021.
Haupt, S.; Seppelt, K. (2002). "Solid State Structures of AsCl₅ and SbCl₅". Zeitschrift für anorganische und allgemeine Chemie. 628 (4): 729–734. doi:10.1002/1521-3749(200205)628:4<729::AID-ZAAC729>3.0.CO;2-E.
Maxson, R. N. (1939). "Phosphorus Pentachloride". Inorganic Syntheses. Vol. 1. pp. 99–100. doi:10.1002/9780470132326.ch34. ISBN 9780470132326.
Wong, Chih Y.; Kennepohl, Dietmar K.; Cavell, Ronald G. (1996). "Neutral Six-Coordinate Phosphorus". Chemical Reviews. 96 (6): 1917–1952. doi:10.1021/cr9410880. PMID 11848816.
Adams, R.; Jenkins, R. L. (1941). "p-Nitrobenzoyl chloride". Organic Syntheses; Collected Volumes, vol. 1, p. 394.
Clayden, Jonathan (2005). Organic chemistry (Reprinted ed.). Oxford: Oxford University Press. ISBN 978-0-19-850346-0.
Burks Jr., J. E. (2004). "Phosphorus(V) chloride". In Paquette, L. (ed.). Encyclopedia of Reagents for Organic Synthesis. New York, NY: J. Wiley & Sons. doi:10.1002/047084289X.rp158. ISBN 0471936235.
Gross, H.; Rieche, A.; Höft, E.; Beyer, E. (1973). "Dichloromethyl methyl ether". Organic Syntheses; Collected Volumes, vol. 5, p. 365.
Spaggiari, A.; Vaccari, D.; Davoli, P.; Torre, G.; Prati, F. (2007). "A Mild Synthesis of Vinyl Halides and gem-Dihalides Using Triphenyl Phosphite−Halogen-Based Reagents". The Journal of Organic Chemistry. 72 (6): 2216–2219. doi:10.1021/jo061346g. ISSN 0022-3263. PMID 17295542.
Schmutzler, R. (1973). "Styrylphosphonic dichloride". Organic Syntheses; Collected Volumes, vol. 5, p. 1005.
Cotton, Frank Albert (1999). Advanced Inorganic Chemistry. Wiley-Interscience. ISBN 978-0-471-19957-1.
Bushkova, O. V.; Yaroslavtseva, T. V.; Dobrovolsky, Yu. A. (4 August 2017). "New lithium salts in electrolytes for lithium-ion batteries (Review)". Russian Journal of Electrochemistry. 53 (7): 677–699. doi:10.1134/S1023193517070035. S2CID 103854243.
Davy, Humphry (1809). "The Bakerian Lecture. An account of some new analytical researches on the nature of certain bodies, particularly the alkalies, phosphorus, sulphur, carbonaceous matter, and the acids hitherto undecomposed; with some general observations on chemical theory". Philosophical Transactions of the Royal Society of London. 99: 39–104. doi:10.1098/rstl.1809.0005. S2CID 98814859. On pp. 94–95, Davy mentioned that when he burned phosphorus in chlorine gas ("oxymuriatic acid gas"), he obtained a clear liquid (phosphorus trichloride) and a white solid (phosphorus pentachloride).
Davy, Humphry (1810). "Researches on the oxymuriatic acid [i.e., chlorine], its nature and combinations; and on the elements of the muriatic acid [i.e., hydrogen chloride]. With some experiments on sulphur and phosphorus, made in the laboratory of the Royal Institution". Philosophical Transactions of the Royal Society of London. 100: 231–257. doi:10.1098/rstl.1810.0016. S2CID 95219058. On p. 257, Davy presented his empirical formula for phosphorus pentachloride: 1 portion of phosphorus to 3 portions of "oxymuriatic gas" (chlorine).
Dulong (1816). "Extrait d'un mémoire sur les combinaisons du phosphore avec l'oxigène" [Extract from a memoir on the compounds of phosphorus with oxygen]. Annales de Chimie et de Physique. 2nd series (in French). 2: 141–150. On p. 148, Dulong presented the correct analysis of phosphorus pentachloride (which is 14.9% phosphorus and 85.1% chlorine by weight, vs. Dulong's values of 15.4% and 84.6%, respectively).

External links

v t e Phosphorus compounds
Phosphides	AlP AsP BP BiP Cs₂P₅ Ca₃P₂ Cd₃P₂ Cu₃P DyP ErP EuP GdP AuP FeP Fe₃P HfP HoP InP LaP Li₃P LuP MoP MoP₂ Mo₃P NbP NdP NpP Np₃P₄ OsP₂ Ru₂P PtP₂ PrP PrP₅ PuP ScP SmP SmP₅ Sr₃P₂ TbP SnP₃ ThP₇ TmP YP YbP ZnP₂ Zn₃P₂ ZrP ZrP₂
Other compounds	PBr₃ PBr₅ PBr₇ PCl₃ PCl₅ P₂Cl₄ PF₃ PF₅ PI₃ PH₃ PN P₃N₅ PO P₂O₃ P₂O₄ P₂O₅ P₄S₃ P₄S_x P₄S₁₀