Fluorination by sulfur tetrafluoride produces organofluorine compounds from oxygen-containing organic functional groups using sulfur tetrafluoride. The reaction has broad scope, and SF4 is an inexpensive reagent. It is however hazardous gas whose handling requires specialized apparatus.[1][2] Thus, for many laboratory scale fluorinations diethylaminosulfur trifluoride ("DAST") is used instead.[3]
Main functional group conversions
Carboxylic acids, amides, esters, and carboxylate salts convert to the trifluoromethyl derivatives, although conditions vary widely:
SF4 + RCO2H → SO2 + RCF3 + HF
For carboxlic acids, the first step gives the acyl fluorides, in keeping with the tendency of SF4 to fluorinate acidic hydroxyl groups:
Species of the type ROSF3 are often invoked as intermediates. In the case of aldehydes and ketones, SF4 is thought to initially add across the double bond to give R2CFOSF3.[4]
Examples
A solution of sulfur tetrafluoride in hydrogen fluoride converts hydroxy-containing amino acids to the fluoro amino acids:[5]
When vicinal diols are combined with SF4, difluorination occurs with inversion of configuration at only one of the alcohols. This was demonstrated in the synthesis of meso-difluorosuccinate from (L)-tartrate and the synthesis of (D)- and (L)-difluorosuccinate from meso-tartrate.[6]
Carbonyl compounds generally react with SF4 to yield geminal difluorides. Reaction times tend to be on the order of hours and yields are moderate.[7] Fluorination of lactones can provide heterocyclic fluorides, although ring opening has been observed for γ-butyrolactone. The six-membered lactide does not experience ring opening.[8]
Fluorination opens epoxides to give either geminal or vicinal difluorides in most cases. Monoarylepoxides give geminal products with migration of the aryl group. Yields are low for sterically hindered di- and trisubstituted epoxides. Epoxides substituted with an ester group give vicinal difluorides via an alkoxysulfur trifluoride intermediate.[9]
Carboxylic acids react with SF4 to afford trifluoromethyl compounds:[10]
C6H13CO2H + 2 SF4 → C6H13CF3 + 2 SOF2 + HF
The formation of the trifluoromethyl derivative sometimes competes with formation of tetrafluoroalkyl ethers, which arise from the reaction between difluoromethyl cation and acyl fluoride.[11][12]
Sulfur tetrafluoride can be used to fluorinate polymers efficiently. This often has a profound effect on polymer properties—fluorination of polyvinyl alcohol, for instance, improves its resistance to strong acids and bases.[13]
A prostaglandin bearing a trifluoromethyl group at C-16 is prepared using sulfur tetrafluoride.[14]
Related reagents
For small scale reactions, SF4 can be inconvenient since it is a gas and stainless steel reaction vessels are required. Many transformations require elevated temperatures. The reaction generates hydrogen fluoride. These concerns have led to interest in alternative fluorinating reagents.[1]Selenium tetrafluoride, a liquid at room temperature, behaves similarly to SF4. Diethylaminosulfur trifluoride (DAST) is a derivative of SF4 that is easier to handle, albeit more expensive.[3]