Addition of Carboxylic Acids to gem-Difluoroalkenes for the Synthesis of gem-Difluoromethylenated Compounds

We herein describe a straightforward protocol for the synthesis of carboxylic esters containing a gem-difluoromethylene unit. Readily available carboxylic acids can act as nucleophiles to add regioselectively to tetrasubstituted or trisubstituted β,β-difluoroacrylates (formal hydroacetoxylation) for the construction of RCO2–CF2 bonds. Thermal conditions are sufficient without the use of catalysts or additives.

A n increasing level of interest in the synthesis of compounds containing the gem-difluoromethylene (-CF 2 -) unit has been seen in recent years. 1 This is due to the ability of the CF 2 group to act as a bioisostere for oxygen or carbonyl in pharmaceutical and agrochemical applications. 2espite the existence of various difluoromethylenation methods, the addition of a nucleophile (Nuc-H) to gemdifluoroalkenes 1, a net hydrofunctionalization process, would be one of the simplest approaches for forming difluoromethylenated products 2 (Scheme 1a).It is well-known that gemdifluoroalkenes are susceptible to nucleophilic attack at the difluoro position due to the inductive effect of the two strong electron-withdrawing F atoms (Scheme 1b). 3 However, the βdifluoro anion intermediate thus generated is unstable and rapidly undergoes β-fluoride elimination to form monofluoroalkenes as the major products, resulting in a net C−F bond functionalization. 4rogress has been made in tackling the challenge of shifting the reactivity toward hydrofunctionalization of gem-difluoroalkenes via the so-called "fluorine-retentive strategy".3a Altman and co-workers successfully demonstrated basecatalyzed hydrothiophenolation 5 and hydrophenolation 5b of trisubstituted difluorostyrenes for the construction of S/O− CF 2 bonds (Scheme 1c).Subsequent development by the same group extended the nucleophile scope to alkyl thiols 5c and alcohols 5d via acid catalysis and photocatalysis, respectively.Nevertheless, intermolecular hydrofunctionalization of gemdifluoroalkenes with heteroatom nucleophiles beyond thiols and alcohols under simple conditions is still very limited. 6e have a continuing interest in using gem-difluoroalkenes as building blocks for valuable fluorinated molecules.Previously, we have developed a series of palladium-catalyzed stereoselective C−F bond functionalizations of tetrasubstituted β,β-difluoroacrylates for the synthesis of monofluoroalkenes (Scheme 1d). 7Herein, we report an unprecedented hydroacetoxylation reaction of the difluoroacrylates, where carbox-ylic acids can act as effective nucleophiles under catalyst-free conditions.The corresponding carboxylic ester products contain the difluoromethylene unit.
Difluoroalkene 1a was used as a standard substrate in the initial studies (Scheme 2).Heating 1a in methanol at 75 °C resulted in a mixture of hydromethoxylation and monofluoroalkene products in low yields (Scheme 2a), and decomposition of the starting material was observed.In stark contrast, heating 1a in acetic acid gave the desired hydroacetoxylation product 2a in 92% isolated yield (Scheme 2b).The reaction could be scaled up to 2.0 mmol with a similar yield.Furthermore, substrates containing benzyl (2b) and heteroaromatic (2c) groups and even a trisubstituted difluoroacrylate (2d) afforded the desired products in good yields.
Regioselective addition of carboxylic acids to alkenes is not a trivial task, 8 and no examples of gem-difluoroalkenes are known to the best of our knowledge.We also screened other fluorinated and nonfluorinated alkenes under the same conditions for comparison, which were all unreactive (Scheme 2c).These included gem-difluoroalkenes A and B without the ester group, monofluoroalkenes C and D, and a nonfluorinated alkene as well as gem-dichloro/dibromoalkene.The results showed that both the difluoro and the ester functionalities of 1 were important for this reaction.
To optimize the reaction conditions further, 1a was reacted with benzoic acid in different solvents and at different temperatures (Table 1).Several organic solvents were screened at 75 °C using 3.0 equiv of the acid, including DMSO, THF, 1,4-dioxane, and MeCN, and the yields were generally quite low (entries 1−4, respectively).A dramatic increase in the yield was observed when the reaction temperature was increased to 150 °C (entries 5 and 6).Alternatively, increasing the amount of acid to 10 equiv could also maintain a good yield at a lower temperature of 75 °C (entry 7).These two sets of conditions (entries 6 and 7) were used in the subsequent exploration of the reaction scope.
Carboxylic acids are inexpensive, readily available, and structurally diverse commodities.By employing various carboxylic acids as nucleophiles under the optimized conditions, tetrasubstituted gem-difluoroalkenes 1 were smoothly transformed into gem-difluoromethylenated esters 2e−t (Scheme 3).In most of the examples, a reaction temperature of 75 °C was sufficient to afford good yields (condition A).
On the contrary, the benzyl-substituted substrate (2t) gave a yield lower than the aryl ones even at increased temperatures.Furthermore, the reaction scope could be extended to trisubstituted gem-difluoroalkene 3a in equally good yields (Scheme 4).Various aryl (4a), heteroaryl (4b and 4c), and alkyl (4d) carboxylic acids were compatible.Drug molecules such as ibuprofen (4e), isoxepac (4f), and dehydrocholic acid (4g) were employed to synthesize the CF 2 -containing ester products.This late-stage functionalization strategy could be attractive in medicinal chemistry for identifying new fluorinated lead compounds.
Intriguingly, trisubstituted gem-difluoroalkene 3a could react with sulfonic acids to generate products 5 containing the RSO 3 −CF 2 bond (Scheme 5).Thus, p-toluenesulfonic acid and camphor-10-sulfonic acid led to products 5a (even at 2.0 mmol scale) and 5b, respectively, in moderate yields.In comparison, a tetrasubstituted substrate such as 1a did not react with these sulfonic acids.We also tested a BINOLderived phosphoric acid with 3a and 1a but found no reaction.
In conclusion, we have discovered a straightforward method for the synthesis of a novel class of gem-difluoromethylenated compounds containing RCO 2 −CF 2 or RSO 3 −CF 2 bonds.Readily available carboxylic acids can undergo regioselective addition to tetrasubstituted and trisubstituted difluoroacrylates with simple heating.No catalysts or additives were required, and the reaction scope could be extended to sulfonic acids.The reaction mechanism is not completely clear at the moment.Both gem-difluoro and ester moieties of 1 were required for the reaction (cf.Scheme 2).We proposed a concerted mechanism (see the Supporting Information) in which the ester group of 1 is protonated by the carboxylic acid while the oxygen of the acid attacks the β-carbon, which is made partially positive due to the two strongly electronwithdrawing F atoms.The resulting enol intermediate tautomerizes to final product 2.This pathway would also avoid the β-F elimination side product.Further exploration of other types of heteroatom nucleophiles is ongoing in our laboratory.

Table 1 .
Optimization of the Reaction a Scheme 3. Addition of Carboxylic Acids to Tetrasubstituted gem-Difluoroalkenes aa Unless specified otherwise, reactions were carried out using 0.2 mmol of 1 for 48 h.Isolated yields.Condition A: 10 equiv of carboxylic acid at 75 °C.Condition B: 3.0 equiv of carboxylic acid at 150 °C.