18-Crown-6 and Its Hydrates:  Bridging but Versatile Hydrogen Bonding. A Theoretical Study of Static and Dynamic Properties

Abstract: Quantum chemical (QM), classical molecular dynamics (MD), and Car-Parrinello (CP-MD) studies are reported for 18-crown-6 (18C6) and its first 18C6(H 2 O) n hydrates, focusing on the D 3d and C i forms of the crown. They reveal the importance of dynamics and the surrounding medium on its conformational and hydrogen-bonding properties. In the gas phase, the two forms of the free crown are found to be quasi-isoenergetic at several computational levels, but during CP-MD simulations, the D 3d form is more mobile th… Show more

“…The low internal energies limit the degree to which these species can surmount barriers to rearrangement to lower energy structures, and thus higher energy conformers may be trapped. This seems to be the case in the B conformer where the neutral bidentate (18c6)H 2 O, mentioned earlier [15] as one of the preferred configurations for the monohydrated neutral system, may first be formed in the argon cluster with a sufficient barrier for K + to replace the bidentate H 2 O inside the 18c6 cavity. We performed DFT calculations on the neutral (18c6)H 2 O system to gain insight on the B conformer, since the aforementioned hydrated alkali metal ion systems [18] showed that the high energy conformers, trapped in our previous experiments, mirror robust neutral structures that failed to undergo rearrangement after ion impact.…”

“…Further calculation details are available in supporting information section. Previous theoretical work [15] indicates that there are three low lying conformations for 18c6(H 2 O), two of which feature single hydrogen bonds and one with a bidentate hydrogen-bonded water. In K + (18c6)(H 2 O), previous ab initio calculations by Feller [10] indicate that the most favored configuration features K + nestled inside the 18c6 cavity with H 2 O coordinated to K + and forming a hydrogen bond with one 18c6 oxygen.…”

Infrared spectroscopy of gas-phase hydrated K+:18-crown-6 complexes: Evidence for high energy conformer trapping using the argon tagging method

“…The low internal energies limit the degree to which these species can surmount barriers to rearrangement to lower energy structures, and thus higher energy conformers may be trapped. This seems to be the case in the B conformer where the neutral bidentate (18c6)H 2 O, mentioned earlier [15] as one of the preferred configurations for the monohydrated neutral system, may first be formed in the argon cluster with a sufficient barrier for K + to replace the bidentate H 2 O inside the 18c6 cavity. We performed DFT calculations on the neutral (18c6)H 2 O system to gain insight on the B conformer, since the aforementioned hydrated alkali metal ion systems [18] showed that the high energy conformers, trapped in our previous experiments, mirror robust neutral structures that failed to undergo rearrangement after ion impact.…”

“…Further calculation details are available in supporting information section. Previous theoretical work [15] indicates that there are three low lying conformations for 18c6(H 2 O), two of which feature single hydrogen bonds and one with a bidentate hydrogen-bonded water. In K + (18c6)(H 2 O), previous ab initio calculations by Feller [10] indicate that the most favored configuration features K + nestled inside the 18c6 cavity with H 2 O coordinated to K + and forming a hydrogen bond with one 18c6 oxygen.…”

Infrared spectroscopy of gas-phase hydrated K+:18-crown-6 complexes: Evidence for high energy conformer trapping using the argon tagging method

“…To the best of our knowledge no QM studies of the complexation of Na + and diaza-18-crown-6 have been reported but many simulation studies have been made involving the complexation of crown ethers and their derivatives with ions. Many insights into the complexation and conformation of the crown ethers have been previously gained by quantum mechanical [24][25][26][27][28][29][30][31][32][33][34][35][36][37][38] and force eld simulations. [39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54] These studies, due to the similarity of 18-crown-6 to the diaza-18-crown-6, provide us with a point of reference for comparison.…”

Quantum mechanical calculations of the interactions between diazacrowns and the sodium cation: an insight into Na⁺ complexation in diazacrown-based synthetic ion channels

“…The wings link to the water molecule O9 via hydrogen bonds (Table 2), and the water molecules also hydrogen bond to the crown ether O atoms, stabilizing the extensive sandwich array of Cu(H 2 NTA)-(H 2 O)Cl units between successive macrocyclic 18-crown-6ether units. Every 18-crown-6-ether ligand associated with two water molecules on opposite sides adopts the conventional conformation with pseudo-D 3d symmetry (Schurhammer et al, 2003). This gives rise to a hydrogen-bonded one-dimensional chain with a succession of Cu(H 2 NTA)(H 2 O)Cl, H 2 O and 18crown-6 molecules.…”

A sandwich strand supramolecular complex: aquachloro(nitrilotriacetato-κ² N,O)copper(II) 18-crown-6-ether trihydrate