“Triphosphorus pentanitride”的意思、由来-开放百科全书

Triphosphorus pentanitride is an inorganic compound with the chemical formula P₃N₅. Containing only phosphorus and nitrogen, this material is classified as a binary 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 nitrogen compounds (such as ammonia and sodium azide);^[1] including a reaction between the elements.^[1]

Similar methods are used to prepared boron nitride (BN) and silicon nitride (Si₃N₄); however the products are generally impure and amorphous.^[2]^[3]

P₃N₅ has also been prepared at room temperature, by a reaction between phosphorus trichloride and sodium amide.^[5]

Reactions

P₃N₅ is thermally less stable than either BN or Si₃N₄, with decomposition to the elements occurring at temperatures above 850 °C:^[2]

It is resistant to weak acids and bases, and insoluble in water at room temperature, however it hydrolyzes upon heating to form the ammonium phosphate salts (NH₄)₂HPO₄ and NH₄H₂PO₄.

Triphosphorus pentanitride reacts with lithium nitride and calcium nitride to form the corresponding salts of PN₄⁷⁻ and PN₃⁴⁻. 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.^[6]

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.^[7]

The structure of α‑P₃N₅ has been determined by single crystal X-ray diffraction, which showed a network structure of edge‑sharing PN₄ tetrahedra.^[8]

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 1960s. 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. 192 °C and tetrameric bromophosphonitrile, (PNBr₂)₄, m.p. 202 °C 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.^[10]^[11]

Several patents have been filed for the use of triphosphorus pentanitride in fire fighting measures.^[12]^[13]

See also

References

1. ^{{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 B|date=1 March 1981|volume=43|issue=3|pages=527–547|doi=10.1080/01418638108222114|bibcode=1981PMagB..43..527V}}
2. ^¹²³{{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}}
3. ^{{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}}
4. ^{{cite journal |doi=10.1021/cm950385y |title=Phosphorus Nitride P3N5: Synthesis, Spectroscopic, and Electron Microscopic Investigations |date=1996 |last1=Schnick |first1=Wolfgang |last2=Lücke |first2=Jan |last3=Krumeich |first3=Frank |journal=Chemistry of Materials |volume=8 |pages=281}}
5. ^{{cite journal |doi=10.1016/j.inoche.2004.03.009 |title=Room temperature route to phosphorus nitride hollow spheres |date=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}}
6. ^{{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|date=1993|volume=76|issue=1-4|pages=183–186|doi=10.1080/10426509308032389}}
7. ^{{cite journal |pmid=12203333 |date=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}}
8. ^{{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|date=1997|volume=36|issue=17|pages=1873–1875|doi=10.1002/anie.199718731}}
9. ^S.T. Henderson and A.M. Marsden, Lamps and Lighting 2nd Ed., Edward Arnlold Press, 1975, {{ISBN|0 7131 3267 1}}
10. ^{{cite journal|last=Hirota|first=Yukihiro|title=Chemical vapor deposition and characterization of phosphorus nitride (P3N5) gate insulators for InP metal-insulator-semiconductor devices|journal=Journal of Applied Physics|date=1982|volume=53|issue=7|pages=5037|doi=10.1063/1.331380|bibcode=1982JAP....53.5037H}}
11. ^{{cite journal|last=Jeong|first=Yoon-Ha|author2=Choi, Ki-Hwan |author3=Jo, Seong-Kue |author4= Kang, Bongkoo |title=Effects of Sulfide Passivation on the Performance of GaAs MISFETs with Photo-CVD Grown P₃N₅ Gate Insulators|journal=Japanese Journal of Applied Physics|date=1995|volume=34|issue=Part 1, No. 2B|pages=1176–1180|doi=10.1143/JJAP.34.1176|bibcode=1995JaJAP..34.1176J}}
12. ^{{Citation|url = http://patentscope.wipo.int/search/en/WO1996010443|title = Phosphorus nitride agents to protect against fires and explosions|accessdate = 2013}}
13. ^{{Citation|url = http://www.patentgenius.com/patent/4063883.html|title = Manufacture of flame-retardant regenerated cellulose fibres|date = December 20, 1977|accessdate = 2013}}