Trifluoramine oxide

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Trifluoramine oxide
Identifiers
3D model (JSmol)
ChemSpider
  • InChI=1S/F3NO/c1-4(2,3)5
    Key: UDOZVPVDQKQJAP-UHFFFAOYSA-N
  • [N+]([O-])(F)(F)F
Properties
F3NO
Molar mass 87.001 g·mol−1
Appearance Colourless gas
Melting point −161 °C (−258 °F; 112 K)
Boiling point −87.5 °C (−125.5 °F; 185.7 K)
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).

Trifluoramine oxide or Nitrogen trifluoride oxide (F3NO) is an inorganic molecule with strong fluorinating powers.

Production[edit]

Trifluoramine oxide was first discovered in 1966 independently by two different groups. One way to produce it was by an electric discharge in a mixture of oxygen on nitrogen trifluoride. Another even less yielding method is by reacting noble metal fluorides (IrF6 or PtF6) with nitric oxide.[1] It is separated by distillation, and can be purified by treating it with potassium hydroxide solution which reacts with the other fluorine containing molecules produced.[1]

An alternate way to produce it is by burning nitric acid in fluorine, followed by rapid cooling.[2] Yet another way is the photochemical reaction of fluorine and nitrosyl fluoride: F2 + FNO → F3NO. This reaction can also happen with heat, but hot fluorine is hard to contain without a reaction with the container.[3] yet another production route is to thermally decompose nitrosyl hexafluoronickelate (NO)2NiF6 → ONF + ONF3 + NiF2.[4]

Properties[edit]

F3NO is a colourless gas at standard conditions. It has a critical temperature of 29.5 °C where the density is 0.593 g/cm3. Critical pressure is about 64 atmospheres.[5]

Trifluoramine oxide has a Trouton's constant of 20.7.[5] Heat of vapourisation at the boiling point is 3.85 kcal/mol.[5]

The F3NO molecule has C3V symmetry, with all the N-F bonds being equivalent. The shape is almost a tetrahedron as N-O bond is similar to the N-F bonds in nature.[1] The nuclear magnetic resonance (NMR) spectrum of 19F has a triplet line around −363 ppm. JNF is 136 Hz.[1] The infra red spectrum N-O stretch at 1687 cm−1, N-F stretch at 743 cm−1, unsymmetrical N-F stretch 887 cm−1 ∠ONF bend 528 cm−1, wither other bands at 558, 528, 801, 929, 1055, 1410, 1622, 1772, 2435, and 3345 cm−1.[1] The dipole moment is 0.0390 D.[6]

The N-O bond has 75% double bond character. This differs from the amine oxides where the amine is much more basic and with a positive charge.[5] The N-O bond-length is 1.158 Å; the N–F bond-length is  1.431 Å ; the bond angles ∠FNF  is  101°; and the three bond angles ∠ONF = 117.[7]

Trifluoramine oxide is toxic, killing rats at a concentration between 200 and 500 ppm.[5]

Reactions[edit]

On fluorinating other compounds nitrosyl fluoride (NOF) is formed.[8] Trifluoramine oxide does not react with water, glass or nickel, making it easier to handle.[1] The "adducts" formed with the pentafluorides, are actually hexafluoride salts containing the F2NO+ ion.[1]

substrate product[8][9] comment
N2F4 NF3
N2O4 NO2F
Cl2 ClF
SF4 SF6
H2O no reaction
aqueous NaOH NO3, F slow
H2SO4 HNO3,HF via F2NO+
SbF5 F2NO+SbF6
AsF5 F2NO+AsF6
PF5 no reaction
BF3 F2NO+BF4,F2NO+B2F7

Trifluoramine oxide reacts slowly with mercury, producing mercury fluorides, and nitrogen oxides.[5] Trifluoramine oxide is fairly stable when heated to 300 °C but slowly breaks up to fluorine and NO2F, NOF, NO2 and NO. The oxygen remains attached to the nitrogen during decomposition.[5]

References[edit]

  1. ^ a b c d e f g Fox, W. B.; MacKenzie, J. S.; Vanderkooi, N.; Sukornick, B.; Wamser, C. A.; Holmes, J. R.; Eibeck, R. E.; Stewart, B. B. (June 1966). "Trifluoramine Oxide". Journal of the American Chemical Society. 88 (11): 2604–2605. doi:10.1021/ja00963a051.
  2. ^ Powell, P. (2013). The Chemistry of the Non-Metals. Springer Science & Business Media. p. 134. ISBN 978-94-011-6904-2.
  3. ^ Fox, W.B.; MacKenzie, J.S.; Vitek, R. (February 1970). "The chemistry of trifluoramine oxide. V. Synthesis of F3 no by photochemical fluorination of nitrosyl fluoride". Inorganic and Nuclear Chemistry Letters. 6 (2): 177–179. doi:10.1016/0020-1650(70)80336-1.
  4. ^ Bartlett, Neil; Passmore, J.; Wells, E. J. (1966). "Nitrogen oxide trifluoride". Chemical Communications (7): 213. doi:10.1039/C19660000213.
  5. ^ a b c d e f g Fox, W. B.; MacKenzie, J. S.; McCarthy, E. R.; Holmes, J. R.; Stahl, R. F.; Juurik, R. (October 1968). "Chemistry of trifluoramine oxide. I. Synthesis and characterization of trifluoramine". Inorganic Chemistry. 7 (10): 2064–2067. doi:10.1021/ic50068a022.
  6. ^ Kirchhoff, William H.; Lide, David R. (July 1969). "Microwave Spectrum, Dipole Moment, and Quadrupole Coupling Constant of Trifluoramine Oxide". The Journal of Chemical Physics. 51 (1): 467–468. Bibcode:1969JChPh..51..467K. doi:10.1063/1.1671761.
  7. ^ Plato, Vernon; Hartford, William D.; Hedberg, Kenneth (November 1970). "Electron-Diffraction Investigation of the Molecular Structure of Trifluoramine Oxide, F3NO". The Journal of Chemical Physics. 53 (9): 3488–3494. doi:10.1063/1.1674522.
  8. ^ a b Fox, William B.; Wamser, C. A.; Eibeck, R.; Huggins, D. K.; MacKenzie, James S.; Juurik, R. (June 1969). "Chemistry of trifluoroamine oxide. II. Reactions with inorganic substrates". Inorganic Chemistry. 8 (6): 1247–1249. doi:10.1021/ic50076a010.
  9. ^ Christe, Karl O.; Maya, Walter (1 June 1969). "Difluoronitronium cation, NF2O+". Inorg. Chem. 8 (6): 1253-1257. doi:10.1021/ic50076a012.
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