$$\rightleftharpoonup{xx}$$
$$\longleftharp{xx}$$,
$$\longrightharp{xx}$$,
Herein, we present the one-pot two-step versatile transformations of CO2 into complex products. The first step of the method concerns the selective 4 e- reduction of CO2 with a hydroborane reductant. This step is critical because selectivity toward the 4 e- reduction is challenging. Very few systems have been reported that describe the selective generation of bis(boryl)acetal23,24,25. In our case, an iron hydride complex catalyzes this selective 4 e- reduction of CO2 with 9-BBN, affording compound 1, under mild conditions (25 °C) and with very short reaction time (45 min) (Figure 2)18. Our study shows that the reaction conditions are very important. In our hand, each attempt to change the concentration, solvent, CO2 pressure and temperature led to the decrease of the yield in compound 1. A longer reaction time is also detrimental because it leads to over-reduction to the methanol level or evolution of the bis(boryl)acetal into several oligomeric compounds. From our experience, it is necessary to verify the outcome of this reduction step by in situ 1H NMR characterization. The reproducibility of the method needs to be probed over several runs.
The in situ condensation reaction of the intermediate 1 with a bulky aniline gives rise to the corresponding imine 2 (Figure 2). This is a straightforward method and compound 2 is readily formed in a high yield (83%). This reaction can also be used to probe the efficiency of the reduction step. This method is the only method enabling the synthesis of imine function from CO2. Moreover, intermediate 1 was proved to be a versatile source of methylene in various condensation reactions leading to the formation of C-N, C-O, C-C and C=C bonds18. This method thus offers a straightforward way of using CO2 as a surrogate of formaldehyde in condensation reactions26.
Intermediate 1 reacts with Ender's carbene to afford compounds 3 or 4, depending on the reaction conditions (Figure 3)20. With the support of in-depth experimental and theoretical study, we were able to explain the observed reactivity. In this case, compound 1 does not react as formaldehyde since boryl moieties remain in compounds 3 and 4. This feature arises from the formation of an unprecedented O-Borylated Breslow intermediate (Figure 3)27,28,29,30,31,32. This intermediate is not observed experimentally but may act as a bifunctional Lewis acid/Lewis base activator toward CO2 to afford compound 3 or leads to the homocoupling of two more carbon centers to afford compound 4. In both products, chiral centers are generated and in the case of compound 4, the two chiral centers, C2 and C3, are obtained in a diastereoselective manner, thanks to the presence of the bridging boryl fragment.
The advances presented herein were possible thanks to the one-pot two-step method employed and to the high and versatile reactivity of intermediate 1 generated from the selective 4e- reduction of CO2. Following a similar method to further improve the scope and the complexity of the synthesized molecules, on-going works are dedicated i) to tune the properties of bis(boryl)acetal in using other hydroborane reductants and ii) to probe different coupling conditions in using other organo-catalysts.