Formation of aqua and tetraammine Cu(II) complexes inside the cavities of cucurbit[6,8]urils: A DFT forecast.

Results of DFT calculations of the structure and thermodynamics of formation of aqua and tetraammine Cu(II) complexes inside CB[n] (n = 6,8) are presented in this study. Formation thermodynamics of the complexes in the cavitands was evaluated by taking into account the most probable number of water molecules inside CB[n]. In this methodology, the complexation was first considered as a substitution reaction in which the guest complex displaces partially or completely the water molecules that are located inside the cavity. The water molecules present in the cavitand were shown to play an important role in the fixation of the guest complex inside the cavity due to the hydrogen bonds with the oxygen portals. The hydration of Cu(II) ion inside CB[6] leads to the formation of an inclusion compound with the formula {[Cu(H2O)4]2+·2H2O}@CB[6] while in CB[8] {[Cu(H2O)6]2+·4H2O}@CB[8] is formed. For the binding of tetraammine Cu(II) complex, CB[8] was determined to be a significantly more suitable "container" than CB[6]. Both a direct embedding of this complex into the CB[8] and another mechanism in which ammonia molecules replace the water molecules in the Cu(II) aqua complex, preexisting in CB[8] were determined to be thermodynamically possible. Both these lead to the formation of the resultant inclusion compound described by the formula {[Cu(NH3)4(H2O)2]2+·4H2O}@CB[8]. Formation thermodynamics of the complexes inside cucurbit[n]urils in aqueous solution is evaluated by taking into account for water molecules in their cavities. The complexation is considered as a substitution reaction in which the guest complex displaces partially or completely the water molecules that exist inside the cavity. The calculated thermodynamic parameters of such a reaction allow for predicting feasible options for the synthesis of inclusion compounds formed in aqueous solutions. [ABSTRACT FROM AUTHOR]