Abstract
The insertion reactions of p-complex (RP) and three-membered ring configuration (RS) of stannylenoid H(2)SnLiF with NH(3), H(2)O and HF have been studied theoretically by quantum chemical calculation. The structures of reactants, precursors, transition states, intermediates and products have been fully optimized at the M06-2X/def2-TZVP level. The single point energy of all fixed points were calculated using the QCISD method. The calculation results show that the three-membered ring configuration is easier to conduct the insertion reaction. Comparing the reaction energy barriers of RP, RS to NH(3), H(2)O and HF, we found that the difficulty of the insertion reaction is NH(3) > H(2)O > HF. The solvent corrected calculation results show that in THF, the reaction energy barrier of RP is lower than that in vacuum, while the reaction energy barrier of RS is higher. This work provides theoretical support for the reaction properties of stannylenoid.