Thiophosphoryl fluoride

Thiophosphoryl fluoride is an inorganic molecular gas with formula containing phosphorus, sulfur and fluorine. It spontaneously ignites in air and burns with a cool flame. The discoverers were able to have flames around their hands without discomfort, and called it "probably one of the coldest flames known". The gas was discovered in 1888.
It is useless for chemical warfare as it burns immediately and is not toxic enough.

Preparation

Thiophosphoryl fluoride was discovered and named by J. W. Rodger and T. E. Thorpe in 1888.
They prepared it by heating arsenic trifluoride and thiophosphoryl chloride together in a sealed glass tube to 150 °C. Also produced in this reaction was silicon tetrafluoride and phosphorus fluorides. By increasing the the proportion of was increased. They observed the spontaneous inflammability. They also used this method:
at 170 °C, and also substituting a mixture of red phosphorus and sulfur, and substituting bismuth trifluoride.
Another way to prepare is to add fluoride to using sodium fluoride in acetonitrile.
A high yield reaction can be used to produce the gas:
Under high pressure phosphorus trifluoride can react with hydrogen sulfide to yield:
Another high pressure production uses phosphorus trifluoride with sulfur.

Reactions

is unstable against moisture or heat. The pure gas is completely absorbed by alkali solutions, producing the fluoride and a thiophosphate, but stable against CaO. The latter can be used to remove or impurities.

Hydrolysis and decomposition

Reaction with neutral water is slow:
Nevertheless, dissociation constants for related acids suggest that the phosphorus atom is at least as electrophilic as in phosphoryl fluoride.
Autodecomposition from heat gives phosphorus fluorides, sulfur, and phosphorus:
Hot PSF₃ reacts with glass, producing, sulfur and elemental phosphorus. If water is present and the glass is leaded, then the hydrofluoric acid and hydrogen sulfide combination produces a black plumbous sulfide deposit on the inner surface.

Oxidation

In air, PSF₃ burns spontaneously with a greyish green flame, producing solid white fumes containing and. The flame is one of the coldest known. With dry oxygen, combustion may not be spontaneous and the flame is yellow.
Thiophosphoryl fluoride reduces oxygenated compounds to give phosphoryl fluoride and sulfur:
The latter reaction also indicates why is not formed from and.
Various oxidants can convert thiophosphoryl fluoride to phosphorus dichloride trifluoride, e.g.:

Nucleophilic substitution

Thiophosphoryl difluoride isocyanate can be formed by reacting with silicon tetraisocyanate at 200 °C in an autoclave.
In general, nucleophilic substitution onto thiophosphoryl fluoride is complex, because free fluoride ions tend to induce disproportionation to hexafluorophosphate and dithiodifluorophosphate. For example, with cesium fluoride:
Thus combines with dimethylamine in solution to produce dimethylaminothiophosphoryl difluoride and difluorophosphate and hexafluorophosphate ions:
PSF₃ reacts with four times its volume of ammonia gas producing ammonium fluoride and a mystery product, possibly.

Miscellaneous

does not react with ether, benzene, carbon disulfide, or pure sulfuric acid. It initiates tetrahydrofuran polymerization.
reacts with in a mass spectrometer to form.

Related compounds

One fluorine can be substituted by iodine to give thiophosphoryl difluoride iodide,. can be converted to hydrothiophosphoryldifluoride,, by reducing it with hydrogen iodide. In, one sulfur forms a bridge between two phosphorus atoms.
Dimethylaminothiophosphoryl difluoride is a foul smelling liquid with a boiling point of 117 °C. It has a Trouton constant of 24.4, and a heat of evaporation of 9530 cal/mole. Alternately it can be produced by fluorination of dimethylaminothiophosphoryl dichloride.

Physical properties

The thiophosphoryl trifluoride molecule shape has been determined using electron diffraction. The interatomic distances are P=S 0.187±0.003 nm, 0.153±0.002 nm and bond angles of bonding is 100.3±2°, The microwave rotational spectrum has been measured for several different isotopologues.
The critical point is at 346 K at 3.82 MPa. The liquid refractive index is 1.353.
The enthalpy of vaporisation 19.6 kJ/mol at boiling point. The enthalpy of vaporisation at other temperatures is a function of temperature T: H=28.85011^0.38 kJ/mol.
The molecule is polar. It has a non-uniform distribution of positive and negative charge which gives it a dipole moment. When an electric field is applied more energy is stored than if the molecules did not respond by rotating. This increases the dielectric constant. The dipole moment of one molecule of thiophosphoryl trifluoride is 0.640 Debye.
The infrared spectrum includes vibrations at 275, 404, 442, 698, 951 and 983 cm⁻¹. These can be used to identify the molecule.