Structure and dynamics of interlayer species in a hydrated Zn-vermiculite. A molecular dynamics study

The structure and dynamics of the interlayer species in hydrated Zn-vermiculite clay at 300 K were studied by means of molecular dynamics calculations. In a water-free structure, the Zn2+ ions adsorb on the surface of the clay layers. In the presence of H2O molecules in the interlayer space Zn(H2O)62+ complexes are built under migration of the ions to the midplane of the interlayer space. The complexes are oriented in the interlayer space so that at least four water molecules interact via their H atoms with the O atoms of the clay surfaces. The calculations show that in the interlamellar space the Zn–water complexes have the same structure and internal dynamics as in aqueous solution. This dynamics was characterized in details on the basis of the calculations. The rotational motion of both the “bound” and “free” molecules proceeds mostly via a reorientation of the HH vector of the molecules. No exchange between the solvating water molecules and the “free” water of the interlayer space was observed in the time-scale of the calculations (2.4 ns). The residence time of the H2O molecules in the second hydration sphere of the cations was computed to be approximately four times longer than in aqueous solution. This increase of the residence time corresponds to the decrease of the diffusion coefficient of the interlayer water, as compared to the molecules in the liquid. The single-particle dynamics of the non-solvating water molecules was studied by the analysis of the intermediate scattering functions and by calculation of the quasi-elastic neutron scattering spectra. The diffusion coefficients D = (0.91 ± 0.11) × 10−9 m2 s−1 was obtained to be very close to that of the H2O molecules in the uncharged clay.

[1]  Hung T. Tran,et al.  Characterization of dynamics and reactivities of solvated ions by ab initio simulations , 2004, J. Comput. Chem..

[2]  S. Woutersen,et al.  Influence of ions on the hydrogen-bond structure in liquid water , 2003 .

[3]  D. Bougeard,et al.  Molecular dynamics study of the structure and dynamics of Zn2+ ion in water , 2003 .

[4]  B. Smit,et al.  Why clays swell , 2002 .

[5]  D. Sparks,et al.  Zinc speciation in a smelter-contaminated soil profile using bulk and microspectroscopic techniques. , 2002, Environmental science & technology.

[6]  V. Barone,et al.  Development and validation of an integrated computational approach for the study of ionic species in solution by means of effective two-body potentials. The case of Zn2+, Ni2+, and Co2+ in aqueous solutions. , 2002, Journal of the American Chemical Society.

[7]  Daniel Tunega,et al.  Theoretical study of adsorption sites on the (001) surfaces of 1:1 clay minerals , 2002 .

[8]  B. Smit,et al.  Adsorption isotherms of water in Li–, Na–, and K–montmorillonite by molecular simulation , 2001 .

[9]  W. Howells,et al.  Dynamics of 2D-water as studied by quasi-elastic neutron scattering and neutron resonance spin-echo , 2001 .

[10]  B. Hudson Inelastic Neutron Scattering: A Tool in Molecular Vibrational Spectroscopy and a Test of ab Initio Methods , 2001 .

[11]  D. Smith,et al.  Simulations of Clay Mineral Swelling and Hydration: Dependence upon Interlayer Ion Size and Charge , 2000 .

[12]  W. Howells,et al.  Quasielastic neutron scattering of two-dimensional water in a vermiculite clay , 2000 .

[13]  Graham D. Williams,et al.  The structure of pore fluids in swelling clays at elevated pressures and temperatures , 1999 .

[14]  D. Bougeard,et al.  A MOLECULAR DYNAMICS STUDY OF STRUCTURE AND SHORT-TIME DYNAMICS OF WATER IN KAOLINITE , 1999 .

[15]  G. Sposito,et al.  Monte Carlo and Molecular Dynamics Simulations of Interfacial Structure in Lithium-Montmorillonite Hydrates , 1997 .

[16]  William N. Lipscomb,et al.  Recent Advances in Zinc Enzymology. , 1996, Chemical reviews.

[17]  Bernd M. Rode,et al.  MONTE CARLO SIMULATIONS OF ZN(II) IN WATER INCLUDING THREE-BODY EFFECTS , 1996 .

[18]  Peter V. Coveney,et al.  Monte Carlo Molecular Modeling Studies of Hydrated Li-, Na-, and K-Smectites: Understanding the Role of Potassium as a Clay Swelling Inhibitor , 1995 .

[19]  Graham D. Williams,et al.  Direct Measurement of the Electric Double-Layer Structure in Hydrated Lithium Vermiculite Clays by Neutron Diffraction , 1995 .

[20]  G. Sposito,et al.  Monte Carlo Simulation of Interlayer Molecular Structure in Swelling Clay Minerals. 1. Methodology , 1995 .

[21]  G. Sposito,et al.  Monte Carlo Simulation of Interlayer Molecular Structure in Swelling Clay Minerals. 2. Monolayer Hydrates , 1995 .

[22]  J. Nicholas,et al.  AB INITIO PERIODIC HARTREE-FOCK INVESTIGATION OF A ZEOLITE ACID SITE , 1994 .

[23]  A. Hess,et al.  An ab Initio Periodic Hartree-Fock Study of Group IA Cations in ANA-Type Zeolites , 1994 .

[24]  A. Soper,et al.  Neutron diffraction study of calcium vermiculite: hydration of calcium ions in a confined environment , 1994 .

[25]  E. Marcos,et al.  Recovering the concept of the hydrated ion for modeling ionic solutions: a Monte Carlo study of zinc(2+) in water , 1993 .

[26]  V. Saunders,et al.  Periodic ab initio Hartree-Fock calculations of the low-symmetry mineral kaolinite , 1992 .

[27]  B. Rode,et al.  Zinc ion in water : intermolecular potential with approximate three-body correction and Monte Carlo simulation , 1991 .

[28]  A. Soper,et al.  The structure of interlayer water in vermiculite , 1991 .

[29]  P. L. Hall,et al.  Quasi-elastic neutron-scattering studies of intercalated molecules in charge-deficient layer silicates. Part 2.—High-resolution measurements of the diffusion of water in montmorillonite and vermiculite , 1985 .

[30]  H. Berendsen,et al.  Molecular dynamics with coupling to an external bath , 1984 .

[31]  P. L. Hall,et al.  Quasi-elastic neutron-scattering studies of the dynamics of intercalated molecules in charge-deficient layer silicates. Part. 1.—Temperature dependence of the scattering from water in Ca2+-exchanged montmorillonite , 1984 .

[32]  Roger Impey,et al.  Hydration and mobility of ions in solution , 1983 .

[33]  P. L. Hall,et al.  Incoherent neutron scattering functions for random jump diffusion in bounded and infinite media , 1981 .

[34]  G. Corongiu,et al.  Monte Carlo simulations of water clusters around Zn++ and a linear Zn++⋅CO2 complex , 1980 .

[35]  A. Mathieson,et al.  Crystal structure of magnesium-vermiculite , 1954 .