Difluoroamino sulfur pentafluoride is a gaseous chemical compound of fluorine, sulfur, and nitrogen. It is unusual in having a hexa-coordinated sulfur atom with a link to nitrogen. Other names for this substance include difluoro(pentafluorosulfur)amine, pentafluorosulfanyldifluoramine, and pentafluorosulfanyl N,N-difluoramine.
Difluoroamino sulfur pentafluoride is a colourless gas at room temperature. The molecule is shaped as a tetragonal bipyramid around the sulfur atom.
To within half a degree the boiling point is -17.5 ðC.
Difluoroamino sulfur pentafluoride is stable at room temperature, but decomposes on the timescale of hours at 80 ðC. Decomposition results in sulfur tetrafluoride and nitrogen trifluoride. It is not stable above 220 ðC. It is stable with water or stainless steel.
When stored in quartz and exposed to ultraviolet light, it decomposes slightly and reacts with silica to make , , , , , and .
The bond between sulfur and nitrogen is quite weak with a dissociation energy of 50 kcal/mol.
The infrared spectrum contains strong absorption bands around 885, 910, and 950 cm<sup>âÂÂ1</sup> due to the bonds with fluorine. If a strong irradiation at 910 cm<sup>âÂÂ1</sup> with a laser takes place the molecules can be disrupted to form , and . By adjusting the frequency of a laser, the break up can be made isotope selective, and also the can be broken up by another nearby frequency.
The fluorine atoms attached to the sulfur are attached at close to 90ð from each other, and the four around the equator are also at 90ð from the nitrogen sulfur bond. The angle subtended by fluorine atoms on the nitrogen atom is about 98ð, and the sulfur-nitrogen-fluorine angle is about 111ð. The distance between sulfur and the four equatorial fluorine atoms is 1.545 à. The axial fluorine to sulfur distance is 1.556 à. Nitrogen sulfur distance is about 1.696 à. The fluorine-nitrogen bond is the shortest in the molecule at 1.378 à.
Difluoroamino sulfur pentafluoride has been prepared by irradiating a mixture of dinitrogen tetrafluoride and sulfur tetrafluoride with ultraviolet light.
This preparation also works with a mixture of dinitrogen tetrafluoride and sulfur chloride pentafluoride. Formation requires the appearance of the radical and chlorine atoms, as well as the nitrogen difluoride radical.
Another way to make difluoroamino sulfur pentafluoride is by heating dinitrogen tetrafluoride and sulfur. This results in the temporary formation of nitrogen difluoride. However the yield is only around 6%, and mostly sulfur tetrafluoride is formed. Yet other substrates for dinitrogen tetrafluoride are disulfur decafluoride or sulfur dioxide or thiophosgene in an electric discharge.
A corona discharge in a sulfur hexafluoride, nitrogen mixture produces a small amount of difluoroamino sulfur pentafluoride. This is important as high voltage equipment is often insulated with this gas combination.
Pentafluorosulfanylamine reacts with fluorine gas to yield difluoroamino sulfur pentafluoride:
Difluoroamino sulfur pentafluoride reacts with Lewis acids like KrF<sup>+</sup>AsF<sub>6</sub><sup>âÂÂ</sup> at -31 ðC to yield SF<sub>6</sub>, Kr, NF<sub>3</sub> and solid N<sub>2</sub>F<sup>+</sup>AsF<sub>6</sub><sup>âÂÂ</sup>. With AsF<sub>5</sub> at -196 ðC (as liquid) it produces solid N<sub>2</sub>F<sup>+</sup>AsF<sub>6</sub><sup>âÂÂ</sup>, SF<sub>6</sub> and trans-N<sub>2</sub>F<sub>2</sub>. Similar products also come from room temperature reactions.
There is a Russian patent to use a combination of alkenes and difluoroamino sulfur pentafluoride as a rocket fuel.
Related substances include fluoroimidotetrafluorosulfur F<sub>4</sub>S=NF and (SF<sub>5</sub>)<sub>2</sub>NF. A tertiary amine exists with formula (SF<sub>5</sub>)<sub>3</sub>N.
Other variant substitutions on the nitrogen atom yield SF<sub>5</sub>NFCl, SF<sub>5</sub>NHF, SF<sub>5</sub>NCl<sub>2</sub> and SF<sub>5</sub>NH<sub>2</sub>.