Shuichi Nosé scite author profile

We report a systematic study of aqueous microsolvation of CdCl 2. The optimized structures and binding energies of the CdCl 2-(H 2 O) n clusters with n = 1-24 have been computed at the B3PW91/ 6-31G** level. The solvation patterns obtained at the DFT level are verified at the MP2/AVTZ level for n < 6. Unlike HgCl 2-(H 2 O) n case, where there are at most three Hg-O w orbital interactions, Cd also establishes four equatorial orbital interactions with water for n > 6 leading to a planar square bipyramid hexacoordination around Cd. The first solvation shell is fully attained with 12 water molecules. At the same level of theory the water binding energies are much larger than those previously found for HgCl 2 due to the stronger Cd-O w interactions arising from the smaller core of Cd. For the largest system studied, CdCl 2-(H 2 O) 24 , both penta-and hexa-coordination stable patterns around Cd are found. However, Born-Opphenheimer molecular dynamics simulations starting from these optimized geometries at 700 K reveal the greater stability of the Cd-pentacoordinated species, where a CdCl 2-(H 2 O) 3 trigonal bipyramid effective solute appears. The Cd-O(water) radial distribution function shows a bimodal distribution with two maxima at 2.4 Å and 4.2 Å, revealing the different coordination spheres, even with such a small number of solvating water molecules.

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A molecular dynamics method for simulations in the canonical ensemble

Nosé

1984

Molecular Physics

7,454

3,358

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Constant pressure molecular dynamics for molecular systems

1983

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A molecular dynamics method for simulations in the canonical ensemble

Nosé¹

2002

Molecular Physics

1,000

945

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Constant Temperature Molecular Dynamics Methods

Nosé

1991

Prog. Theor. Phys. Suppl.

1,045

457

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A study of solid and liquid carbon tetrafluoride using the constant pressure molecular dynamics technique

Nosé¹,

Klein²

1983

The Journal of Chemical Physics

195

105

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Constant-temperature molecular dynamics

Nosé¹

1990

J. Phys.: Condens. Matter

164

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An Improved Symplectic Integrator for Nosé-Poincaré Thermostat

Nosé

2001

J. Phys. Soc. Jpn.

125

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Shuichi Nosé

A unified formulation of the constant temperature molecular dynamics methods

A molecular dynamics method for simulations in the canonical ensemble

Constant pressure molecular dynamics for molecular systems

A molecular dynamics method for simulations in the canonical ensemble

Constant Temperature Molecular Dynamics Methods

A study of solid and liquid carbon tetrafluoride using the constant pressure molecular dynamics technique

Constant-temperature molecular dynamics

An Improved Symplectic Integrator for Nosé-Poincaré Thermostat

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