NMR Studies of Structure and Dynamics of Liquid Molecules Confined in Extended Nanospaces

We fabricated an NMR cell equipped with 10-100 nm scale spaces oil a glass substrate (called extended nanospaces), and investigated molecular structure and dynamics of water confined in the extended nanospaces by H-1 NMR chemical shift (delta(H)) and H-1 and H-2 NMR spin-lattice relaxation rate (H-1- and H-2-1/T-1), H-1 NMR spin-spin relaxation rate (H-1-1/T-2), and H-1 NMR rotating-frame spin-lattice relaxation rate (H-1-1/T-1 rho) measurements of H2O and (H2O)-H-2. The delta(H) and H-1- and H-2-1/T-1 results showed that size-confinement produces slower translational motions and higher proton mobility of water, but does not affect the hydrogen-bonding structure and rotational motions. Such unique phenomena appeared in the space size of 40 to 800 nm. However, the H-1-1/T-1 value at 40 nm was still different from that in 4 nm porous nanomaterial, because translational and rotational motions were inhibited for H2O molecules in the nanomaterial. By examining temperature- and deuterium-dependence of the H-1-1/T-1 values, the molecular translational motions of the confined water were found to be controlled by protonic diffusion invoking a proton hopping pathway between adjacent water rather than hydrodynamic translational diffusion. Furthermore, we clarified that proton exchange between adjacent water molecules in extended nanospaces could be enhanced by the chemical exchange of protons between water and SiOH groups on glass surfaces, ( SiO-center dot center dot center dot H+center dot center dot center dot H2O) + H2O -> SiO- + (H3O+ + H2O) -> SiO- + (H2O + H3O+), based on H-1-1/T-2 measurements. An enhancement of proton exchange rate of water due to the reduction of space sizes was verified from the results of H-1-1/T-1 rho values, and the rate of water in the 100 nm sized spaces is larger by a factor of more than ten from that of bulk water. Such size-confinement effects were distinctly observed for hydrogen-bond solvents with strong proton-donating ability, while they did not appear for aprotic and nonpolar solvent cases. Based oil these NMR results, we suggested that ail intermediate phase, in which protons migrate through a hydrogen-bonding network and the water molecules are loosely coupled within 50 nm from the Surface, exists mainly in extended nanospaces. This model could be supported by a three-phase theory based oil the weight average of three phases invoking the bulk, adsorbed, and intermediate phases.