Triphosphorus pentanitride: Difference between revisions

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	\| MolarMass = 162.955		\| MolarMass = 162.955
	\| Appearance = White solid		\| Appearance = White solid
	\| Density = ά-P<sub>3</sub>N<sub>5</sub> = 2.77 g/cm<sup>3</sup>		\| Density = α-P<sub>3</sub>N<sub>5</sub> = 2.77 g/cm<sup>3</sup>
	\| MeltingPt = decomposes at ≥850°C		\| MeltingPt = decomposes at ≥850°C
	\| Solubility = insoluable}}		\| Solubility = insoluable}}
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	}}		}}

	'''Triphosphorus pentanitride''' is an ] with the ] ]]. It is a ] ~~non-metal~~ nitride; a ~~family of~~ compounds ~~which includes~~ ] and ].		'''Triphosphorus pentanitride''' is an ] with the ] ]]. Containing only phosphorus and nitrogen, this material is classified as a ] nitride. Related compounds are ] and ]. No applications have been developed for this material, which remains a topic of research. It is a white solid, although samples often appear colored owing to impurities.

	== Synthesis ==		== Synthesis ==
	Triphosphorus pentanitride can be produced by reactions between various ] and ] ~~compounds,~~<ref name=Wolfgang></ref> including a reaction between the elements.<ref>{{cite journal\|last=Vepřek\|first=S.\|author2=Iqbal, Z. \|author3=Brunner, J. \|author4= Schärli, M. \|title=Preparation and properties of amorphous phosphorus nitride prepared in a low-pressure plasma\|journal=Philosophical Magazine Part B\|date=1 March 1981\|volume=43\|issue=3\|pages=527–547\|doi=10.1080/01418638108222114}}</ref> These methods of preparation are similar to those used for ] and ]; however the products are generally impure and ].<ref name=Wolfgang>{{cite journal\|last=Schnick\|first=Wolfgang\|title=Solid-State Chemistry with Nonmetal Nitrides\|journal=Angewandte Chemie International Edition in English\|date=1 June 1993\|volume=32\|issue=6\|pages=806–818\|doi=10.1002/anie.199308061}}</ref>		Triphosphorus pentanitride can be produced by reactions between various ](V) and various ] reagents:<ref name=Wolfgang></ref> including a reaction between the elements.<ref>{{cite journal\|last=Vepřek\|first=S.\|author2=Iqbal, Z. \|author3=Brunner, J. \|author4= Schärli, M. \|title=Preparation and properties of amorphous phosphorus nitride prepared in a low-pressure plasma\|journal=Philosophical Magazine Part B\|date=1 March 1981\|volume=43\|issue=3\|pages=527–547\|doi=10.1080/01418638108222114}}</ref>

	:3 ] + 5 ] → P<sub>3</sub>N<sub>5</sub> + 15 ]		:3 ] + 5 ] → P<sub>3</sub>N<sub>5</sub> + 15 ]
	:3 PCl<sub>5</sub> + 15 ] → P<sub>3</sub>N<sub>5</sub> + 15 ] + 5 N<sub>2</sub><ref>{{cite journal\|last=Meng\|first=Zhaoyu\|author2=Peng, Yiya \|author3=Yang, Zhiping \|author4= Qian, Yitai \|title=Synthesis and Characterization of Amorphous Phosphorus Nitride.\|journal=Chemistry Letters\|date=1 January 2000\|issue=11\|pages=1252–1253\|doi=10.1246/cl.2000.1252}}</ref>		:3 PCl<sub>5</sub> + 15 ] → P<sub>3</sub>N<sub>5</sub> + 15 ] + 5 N<sub>2</sub>
			Similar methods are used to prepared ] and ]; however the products are generally impure and ].<ref name=Wolfgang>{{cite journal\|last=Schnick\|first=Wolfgang\|title=Solid-State Chemistry with Nonmetal Nitrides\|journal=Angewandte Chemie International Edition in English\|date=1 June 1993\|volume=32\|issue=6\|pages=806–818\|doi=10.1002/anie.199308061}}</ref><ref>{{cite journal\|last=Meng\|first=Zhaoyu\|author2=Peng, Yiya \|author3=Yang, Zhiping \|author4= Qian, Yitai \|title=Synthesis and Characterization of Amorphous Phosphorus Nitride.\|journal=Chemistry Letters\|date=1 January 2000\|issue=11\|pages=1252–1253\|doi=10.1246/cl.2000.1252}}</ref>

	~~Pure,~~ ], ~~triphosphorus~~ ~~pentanitride has~~ been produced by ~~reactions~~ ~~between~~ ] and ]<ref>{{cite journal \|doi=10.1021/cm950385y \|title=Phosphorus Nitride P3N5: Synthesis, Spectroscopic, and Electron Microscopic Investigations \|year=1996 \|last1=Schnick \|first1=Wolfgang \|last2=Lücke \|first2=Jan \|last3=Krumeich \|first3=Frank \|journal=Chemistry of Materials \|volume=8 \|pages=281}}</ref> or ].<ref name=Wolfgang></ref>		] samples have been produced by the reaction of ] and ]:<ref>{{cite journal \|doi=10.1021/cm950385y \|title=Phosphorus Nitride P3N5: Synthesis, Spectroscopic, and Electron Microscopic Investigations \|year=1996 \|last1=Schnick \|first1=Wolfgang \|last2=Lücke \|first2=Jan \|last3=Krumeich \|first3=Frank \|journal=Chemistry of Materials \|volume=8 \|pages=281}}</ref> or ].<ref name=Wolfgang></ref>

	:~~] + 2 NH<sub>4</sub>Cl → P<sub>3</sub>N<sub>5</sub> + 8 HCl~~		:(NPCl<sub>2</sub>)<sub>3</sub>]] + 2 NH<sub>4</sub>Cl → P<sub>3</sub>N<sub>5</sub> + 8 HCl

	:3 ] + 5 NH<sub>4</sub>Cl → P<sub>3</sub>N<sub>5</sub> + 20 HCl		:3 ] + 5 NH<sub>4</sub>Cl → P<sub>3</sub>N<sub>5</sub> + 20 HCl

	P<sub>3</sub>N<sub>5</sub> has also been prepared at room temperature, by a reaction between ] and ].<ref>{{cite journal \|doi=10.1016/j.inoche.2004.03.009 \|title=Room temperature route to phosphorus nitride hollow spheres \|year=2004 \|last1=Chen \|first1=Luyang \|last2=Gu \|first2=Yunle \|last3=Shi \|first3=Liang \|last4=Yang \|first4=Zeheng \|last5=Ma \|first5=Jianhua \|last6=Qian \|first6=Yitai \|journal=Inorganic Chemistry Communications \|volume=7 \|issue=5 \|pages=643}}</ref>		P<sub>3</sub>N<sub>5</sub> has also been prepared at room temperature, by a reaction between ] and ].<ref>{{cite journal \|doi=10.1016/j.inoche.2004.03.009 \|title=Room temperature route to phosphorus nitride hollow spheres \|year=2004 \|last1=Chen \|first1=Luyang \|last2=Gu \|first2=Yunle \|last3=Shi \|first3=Liang \|last4=Yang \|first4=Zeheng \|last5=Ma \|first5=Jianhua \|last6=Qian \|first6=Yitai \|journal=Inorganic Chemistry Communications \|volume=7 \|issue=5 \|pages=643}}</ref>
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	== Reactions ==		== Reactions ==
	P<sub>3</sub>N<sub>5</sub> is thermally less stable than either BN or Si<sub>3</sub>N<sub>4</sub>, with ] to the elements occurring at temperatures above 850°C.<ref name = Wolfgang></ref>		P<sub>3</sub>N<sub>5</sub> is thermally less stable than either BN or Si<sub>3</sub>N<sub>4</sub>, with ] to the elements occurring at temperatures above 850 °C:<ref name = Wolfgang></ref>

	:2 P<sub>3</sub>N<sub>5</sub> → 6 PN + 2 N<sub>2</sub> → 3 P<sub>2</sub> + 5 N<sub>2</sub>		:2 P<sub>3</sub>N<sub>5</sub> → 6 PN + 2 N<sub>2</sub>
			:2 PN → P<sub>2</sub> + N<sub>2</sub>

	It is resistant to weak acids and bases, and insoluble in water at room temperature, however it ~~will react with water~~ upon heating to form ~~various ammonium~~ ~~phosphate~~ ~~salts~~.		It is resistant to weak acids and bases, and insoluble in water at room temperature, however it ] upon heating to form ] and ].

		⚫	Triphosphorus pentanitride reacts with ] and ] to form the corresponding salts of PN<sub>4</sub><sup>7-</sup> and PN<sub>3</sub><sup>4-</sup>. Heterogenous ammonolyses of triphosphorus pentanitride gives imides such as HPN<sub>2</sub> and HP<sub>4</sub>N<sub>7</sub>. It has been suggested that these compounds may have applications as ] and ]s.<ref>{{cite journal\|last=Schnick\|first=Wolfgang\|title=Phosphorus(V) Nitrides: Preparation, Properties, and Possible Applications of New Solid State Materials with Structural Analogies to Phosphates and Silicates\|journal=Phosphorus, Sulfur, and Silicon and the Related Elements\|year=1993\|volume=76\|issue=1-4\|pages=183–186\|doi=10.1080/10426509308032389}}</ref>
	:P<sub>3</sub>N<sub>5</sub> + 12 H<sub>2</sub>O → 3 ] + 5 ] → 2 ] + ]

⚫	Triphosphorus pentanitride ~~can react~~ with ] and ] to form a ~~variety~~ of ~~compounds including Li~~<sub>7</sub>PN<~~sub~~>4</~~sub~~> and Ca<sub>2</sub>PN<~~sub~~>3</~~sub~~>. Heterogenous ammonolyses of triphosphorus pentanitride ~~can from triphosphorus pentanitride~~ ~~immides~~ such as HPN<sub>2</sub> and HP<sub>4</sub>N<sub>7</sub>. It has been suggested that these compounds may have applications as ] and ]s.<ref>{{cite journal\|last=Schnick\|first=Wolfgang\|title=Phosphorus(V) Nitrides: Preparation, Properties, and Possible Applications of New Solid State Materials with Structural Analogies to Phosphates and Silicates\|journal=Phosphorus, Sulfur, and Silicon and the Related Elements\|year=1993\|volume=76\|issue=1-4\|pages=183–186\|doi=10.1080/10426509308032389}}</ref>

	== Structure and properties ==		== Structure and properties ==
		⚫	Several different ] are known for triphosphorus pentanitride. The alpha‑form of triphosphorus pentanitride (α‑P<sub>3</sub>N<sub>5</sub>) is encountered at atmospheric pressure and exists at pressures up to 6 ], at which point it converts to the gamma‑variety (γ‑P<sub>3</sub>N<sub>5</sub>) of the compound. ] indicates that a third, delta‑variety (δ‑P<sub>3</sub>N<sub>5</sub>), will form at around 43 Gpa with a ]-like structure.<ref>{{cite journal \|pmid=12203333 \|year=2002 \|last1=Kroll \|first1=P \|last2=Schnick \|first2=W \|title=A density functional study of phosphorus nitride P3N5: Refined geometries, properties, and relative stability of alpha-P3N5 and gamma-P3N5 and a further possible high-pressure phase delta-P3N5 with kyanite-type structure \|volume=8 \|issue=15 \|pages=3530–7 \|doi=10.1002/1521-3765(20020802)8:15<3530::AID-CHEM3530>3.0.CO;2-6 \|journal=Chemistry}}</ref>
	Although white when of high purity, triphosphorus pentanitride can take on a number of subtle buff shades if not highly pure.

⚫	~~There are several~~ different ] of triphosphorus pentanitride~~, which occur at different ]s~~. The alpha‑form of triphosphorus pentanitride (~~ά‑P~~<sub>3</sub>N<sub>5</sub>) is ~~the form~~ encountered at atmospheric pressure and exists at pressures up to 6 ], at which point it converts to the gamma‑variety (γ‑P<sub>3</sub>N<sub>5</sub>) of the compound. ] indicates that a third, delta‑variety (δ‑P<sub>3</sub>N<sub>5</sub>), will form at around 43 Gpa with a ]-like structure.<ref>{{cite journal \|pmid=12203333 \|year=2002 \|last1=Kroll \|first1=P \|last2=Schnick \|first2=W \|title=A density functional study of phosphorus nitride P3N5: Refined geometries, properties, and relative stability of alpha-P3N5 and gamma-P3N5 and a further possible high-pressure phase delta-P3N5 with kyanite-type structure \|volume=8 \|issue=15 \|pages=3530–7 \|doi=10.1002/1521-3765(20020802)8:15<3530::AID-CHEM3530>3.0.CO;2-6 \|journal=Chemistry}}</ref>

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	The structure of ~~ά‑P~~<sub>3</sub>N<sub>5</sub> has been determined by ] ], which showed a network structure of edge‑sharing PN<sub>4</sub> tetrahedra.<ref>{{cite journal\|last=Horstmann\|first=Stefan\|author2=Irran, Elisabeth \|author3=Schnick, Wolfgang \|title=Synthesis and Crystal Structure of Phosphorus(V) Nitrideα-P3N5\|journal=Angewandte Chemie International Edition in English\|year=1997\|volume=36\|issue=17\|pages=1873–1875\|doi=10.1002/anie.199718731}}</ref>		The structure of α‑P<sub>3</sub>N<sub>5</sub> has been determined by ] ], which showed a network structure of edge‑sharing PN<sub>4</sub> tetrahedra.<ref>{{cite journal\|last=Horstmann\|first=Stefan\|author2=Irran, Elisabeth \|author3=Schnick, Wolfgang \|title=Synthesis and Crystal Structure of Phosphorus(V) Nitrideα-P3N5\|journal=Angewandte Chemie International Edition in English\|year=1997\|volume=36\|issue=17\|pages=1873–1875\|doi=10.1002/anie.199718731}}</ref>

	== Applications ==		== Applications ==

Revision as of 17:31, 29 October 2014

Triphosphorus pentanitride
Names
IUPAC name Triphosphorus pentanitride
Other names Phosphorus(V) nitride, Phosphorus nitride
Identifiers
CAS Number	12136-91-3
ECHA InfoCard	100.032.018
CompTox Dashboard (EPA)	DTXSID6093968
Properties
Chemical formula	P₃N₅
Molar mass	162.955
Appearance	White solid
Density	α-P₃N₅ = 2.77 g/cm
Melting point	decomposes at ≥850°C
Solubility in water	insoluable
Except where otherwise noted, data are given for materials in their standard state (at 25 °C , 100 kPa). Infobox references

Chemical compound

Triphosphorus pentanitride is an inorganic compound with the chemical formula P₃ N₅. Containing only phosphorus and nitrogen, this material is classified as a binary nitride. Related compounds are boron nitride and silicon nitride. No applications have been developed for this material, which remains a topic of research. It is a white solid, although samples often appear colored owing to impurities.

Synthesis

Triphosphorus pentanitride can be produced by reactions between various phosphorus(V) and various nitrogen reagents: including a reaction between the elements.

3 PCl₅ + 5 NH₃ → P₃N₅ + 15 HCl

3 PCl₅ + 15 NaN₃ → P₃N₅ + 15 NaCl + 5 N₂

Similar methods are used to prepared boron nitride and silicon nitride; however the products are generally impure and amorphous.

Crystalline samples have been produced by the reaction of ammonium chloride and hexachlorocyclotriphosphazene: or phosphorus pentachloride.

(NPCl₂)₃]] + 2 NH₄Cl → P₃N₅ + 8 HCl

3 PCl₅ + 5 NH₄Cl → P₃N₅ + 20 HCl

P₃N₅ has also been prepared at room temperature, by a reaction between phosphorus trichloride and sodium amide.

3 PCl₃ + 5 NaNH₂ → P₃N₅ + 5 NaCl + 4 HCl + 3 H₂

Reactions

P₃N₅ is thermally less stable than either BN or Si₃N₄, with decomposition to the elements occurring at temperatures above 850 °C:

2 P₃N₅ → 6 PN + 2 N₂

2 PN → P₂ + N₂

It is resistant to weak acids and bases, and insoluble in water at room temperature, however it hydrolyzes upon heating to form ] and NH₄H₂PO₄.

Triphosphorus pentanitride reacts with lithium nitride and calcium nitride to form the corresponding salts of PN₄ and PN₃. Heterogenous ammonolyses of triphosphorus pentanitride gives imides such as HPN₂ and HP₄N₇. It has been suggested that these compounds may have applications as solid electrolytes and pigments.

Structure and properties

Several different polymorphs are known for triphosphorus pentanitride. The alpha‑form of triphosphorus pentanitride (α‑P₃N₅) is encountered at atmospheric pressure and exists at pressures up to 6 GPa, at which point it converts to the gamma‑variety (γ‑P₃N₅) of the compound. Computational chemistry indicates that a third, delta‑variety (δ‑P₃N₅), will form at around 43 Gpa with a Kyanite-like structure.

Polymorph	Density (g/cm)
α‑P₃N₅	2.77
γ‑P₃N₅	3.65
δ‑P₃N₅	4.02

The structure of α‑P₃N₅ has been determined by single crystal X-ray diffraction, which showed a network structure of edge‑sharing PN₄ tetrahedra.

Applications

Triphosphorus pentanitride currently has no large scale applications although it had found use as a gettering material for incandescent lamps; replacing various mixtures containing red phosphorus in the late 1960's. The lighting filaments are dipped into a suspension of P₃N₅ prior to being sealed into the bulb. After bulb closure, but whilst still on the pump, the lamps are lit, causing the P₃N₅ to thermally decompose into its constituent elements. Much of this is removed by the pump but enough P₄ vapor remains to react with any residual oxygen inside the bulb. Once the vapor pressure of P₄ is low enough either filler gas is admitted to the bulb prior to sealing off or, if a vacuum atmosphere is desired the bulb is sealed off at that point. The high decomposition temperature of P₃N₅ allows sealing machines to run faster and hotter than was possible using red phosphorus.

Related halogen containing polymers, trimeric bromophosphonitrile, (PNBr₂)₃, m.p. 192C and tetrameric bromophosphonitrile, (PNBr₂)₄, m.p. 202C find similar lamp gettering applications for tungsten halogen lamps, where they perform the dual processies of gettering and precise halogen dosing.

It has also been investigated as a new material for semiconductor based electronics; particularly as a gate insulator in metal-insulator-semiconductor devices.

Several patents have been filed for the use of triphosphorus pentanitride in fire fighting measures.

References

^ Schnick, Wolfgang (1 June 1993). "Solid-State Chemistry with Nonmetal Nitrides". Angewandte Chemie International Edition in English. 32 (6): 806–818. doi:10.1002/anie.199308061.
Vepřek, S.; Iqbal, Z.; Brunner, J.; Schärli, M. (1 March 1981). "Preparation and properties of amorphous phosphorus nitride prepared in a low-pressure plasma". Philosophical Magazine Part B. 43 (3): 527–547. doi:10.1080/01418638108222114.
Meng, Zhaoyu; Peng, Yiya; Yang, Zhiping; Qian, Yitai (1 January 2000). "Synthesis and Characterization of Amorphous Phosphorus Nitride". Chemistry Letters (11): 1252–1253. doi:10.1246/cl.2000.1252.
Schnick, Wolfgang; Lücke, Jan; Krumeich, Frank (1996). "Phosphorus Nitride P3N5: Synthesis, Spectroscopic, and Electron Microscopic Investigations". Chemistry of Materials. 8: 281. doi:10.1021/cm950385y.
Chen, Luyang; Gu, Yunle; Shi, Liang; Yang, Zeheng; Ma, Jianhua; Qian, Yitai (2004). "Room temperature route to phosphorus nitride hollow spheres". Inorganic Chemistry Communications. 7 (5): 643. doi:10.1016/j.inoche.2004.03.009.
Schnick, Wolfgang (1993). "Phosphorus(V) Nitrides: Preparation, Properties, and Possible Applications of New Solid State Materials with Structural Analogies to Phosphates and Silicates". Phosphorus, Sulfur, and Silicon and the Related Elements. 76 (1–4): 183–186. doi:10.1080/10426509308032389.
Kroll, P; Schnick, W (2002). "A density functional study of phosphorus nitride P3N5: Refined geometries, properties, and relative stability of alpha-P3N5 and gamma-P3N5 and a further possible high-pressure phase delta-P3N5 with kyanite-type structure". Chemistry. 8 (15): 3530–7. doi:10.1002/1521-3765(20020802)8:15<3530::AID-CHEM3530>3.0.CO;2-6. PMID 12203333.
Horstmann, Stefan; Irran, Elisabeth; Schnick, Wolfgang (1997). "Synthesis and Crystal Structure of Phosphorus(V) Nitrideα-P3N5". Angewandte Chemie International Edition in English. 36 (17): 1873–1875. doi:10.1002/anie.199718731.
S.T. Henderson and A.M. Marsden, Lamps and Lighting 2nd Ed., Edward Arnlold Press, 1975, ISBN 0 7131 3267 1
Hirota, Yukihiro (1982). "Chemical vapor deposition and characterization of phosphorus nitride (P3N5) gate insulators for InP metal-insulator-semiconductor devices". Journal of Applied Physics. 53 (7): 5037. doi:10.1063/1.331380.
Jeong, Yoon-Ha; Choi, Ki-Hwan; Jo, Seong-Kue; Kang, Bongkoo (1995). "Effects of Sulfide Passivation on the Performance of GaAs MISFETs with Photo-CVD Grown P₃N₅ Gate Insulators". Japanese Journal of Applied Physics. 34 (Part 1, No. 2B): 1176–1180. doi:10.1143/JJAP.34.1176.
Phosphorus nitride agents to protect against fires and explosions, retrieved 2013 {{citation}}: Check date values in: |accessdate= (help)
Manufacture of flame-retardant regenerated cellulose fibres, December 20, 1977, retrieved 2013 {{citation}}: Check date values in: |accessdate= (help)

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

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