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Molecular dynamics simulation coordinated metal ions

The structure of the adsorbed ion coordination shell is determined by the competition between the water-ion and the metal-ion interactions, and by the constraints imposed on the water by the metal surface. This structure can be characterized by water-ion radial distribution functions and water-ion orientational probability distribution functions. Much is known about this structure from X-ray and neutron scattering measurements performed in bulk solutions, and these are generally in agreement with computer simulations. The goal of molecular dynamics simulations of ions at the metal/water interface has been to examine to what degree the structure of the ion solvation shell is modified at the interface. [Pg.147]

However, details of this process including the mode of urea binding, the protonation state of individual surround protein residues, and the exact identity of the nucleophile are still under debate. Cyanate also was proposed as a possible intermediate in the urease mechanism (33). Recent quantum chemical calculations and molecular dynamics simulations indicated that hydrolytic and ehmination mechanisms might indeed compete, and that both are viable reaction channels for urease (34—37). Finally, an important issue is Why does urease require nickel as the metal of choice, whereas most other metallohydrolases use zinc While it was speculated that, inter alia, the relatively rigid and stable coordination environment around the Ni(II) ions as opposed to the higher kinetic lability and lower thermodynamic stability of Zn(II) complexes might play a role (31), this fundamental question has not yet been answered. [Pg.492]


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See also in sourсe #XX -- [ Pg.115 ]




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Dynamic coordination

Dynamic simulation

Dynamical simulations

Ion coordination

Ion dynamics

Ion simulation

Metal ion coordination

Metallic molecular

Molecular Dynamics Simulation

Molecular dynamics coordination

Molecular ion

Molecular metal

Molecular simulations

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