Coupling a polarizable water model to the hydrated ion–water interaction potential: A test on the Cr3+ hydration

Martı́nez, José M.; Hernández-Cobos, Jorge; Saint-Martı́n, Humberto; Pappalardo, Rafael R.; Ortega‐Blake, Iván; Marcos, Enrique Sánchez

doi:10.1063/1.480799

Cited by 45 publications

(41 citation statements)

References 67 publications

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“…1,2 The octahedral structure of [Cr(H 2 O) 6 ] 3ϩ has been determined by several experimental techniques such as X-ray diffraction (XRD), [3][4][5] neutron diffraction (ND), 6,7 large-angle X-ray diffraction (LAXS), 8 and extended X-ray absorption fine structure (EXAFS) 9,10 methods. In theoretical investigations, Monte Carlo (MC) 11,12 and molecular dynamics (MD) [13][14][15] simulations based on numerous approaches of water-water interaction models and ion-water interaction potential construction have been performed to determine the structure of the second hydration shell of Cr(H 2 O) 6 3ϩ , keeping the Cr(III) ion's kinetically inert first hydration shell at a rigid geometry. By using variable high field 17 O NMR to observe fast ligand exchange processes between the second hydration shell and the bulk for the hydrated Cr(III) ion, the exchange rate k ex 298 of (7.8 Ϯ 0.2) ϫ 10 9 s Ϫ1 was obtained, corresponding to an average lifetime of 128 ps for water molecules in the second hydration shell.…”

Section: Introductionmentioning

confidence: 99%

Structure and dynamics of the Cr(III) ion in aqueous solution: Ab initio QM/MM molecular dynamics simulation

2004

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Structural and dynamical properties of the Cr(III) ion in aqueous solution have been investigated using a combined ab initio quantum mechanical/molecular mechanical (QM/MM) molecular dynamics simulation. The hydration structure of Cr(III) was determined in terms of radial distribution functions, coordination numbers, and angular distributions. The QM/MM simulation gives coordination numbers of 6 and 15.4 for the first and second hydration shell, respectively. The first hydration shell is kinetically very inert but by no means rigid and variations of the first hydration shell geometry lead to distinct splitting in the vibrational spectra of Cr(H(2)O)(6) (3+). A mean residence time of 22 ps was obtained for water ligands residing in the second hydration shell, which is remarkably shorter than the experimentally estimated value. The hydration energy of -1108 +/- 7 kcal/mol, obtained from the QM/MM simulation, corresponds well to the experimental hydration enthalpy value.

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Section: Introductionmentioning

confidence: 99%

Structure and dynamics of the Cr(III) ion in aqueous solution: Ab initio QM/MM molecular dynamics simulation

2004

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“…Schemes that relax this constraint can be called self-consistent embedding schemes (or polarized embedding schemes). However, self-consistency is difficult to achieve because it requires a polarizable MM force field [157][158][159][160][161][162][163][164][165][166][167][168][169], which has the flexibility to respond to perturbation by an external electric field. Such flexibility is not available in today's most popular MM force fields, although research to develop a polarizable force field has received much attention [164,166].…”

Section: Electrostatic Embedding?mentioning

confidence: 99%

QM/MM: what have we learned, where are we, and where do we go from here?

2006

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This paper briefly reviews the current status of the most popular methods for combined quantum mechanical/molecular mechanical (QM/MM) calculations, including their advantages and disadvantages. There is a special emphasis on very general link-atom methods and various ways to treat the charge near the boundary. Mechanical and electric embedding are contrasted. We consider methods applicable to gas-phase organic chemistry, liquid-phase organic and organometallic chemistry, biochemistry, and solid-state chemistry. Then we review some recent tests of QM/MM methods and summarize what we learn about QM/MM from these studies. We also discuss some available software. Finally, we present a few comments about future directions of research in this exciting area, where we focus on more intimate blends of QM with MM.

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“…Investigating in detail the effect of the reaction field (2 nd and higher order shells) on a few representative Since the B3LYP/6-31G** IEFPCM and COSMO computations are plagued by convergence problems (not perceived at variational level but solely at the vibrational analysis), we attempted a simpler computational approach avoiding diffuse functions and performed an explicit solvation assuming the initial Cr[6-12] structure already investigated by Martinez et al (2000). The interaction energy between the Cr 3ϩ hexahydrate and its hydration shell, obtained from the Harthree-Fock energies of the interacting molecules: -electrostatic contributions).…”

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confidence: 99%

Ab-initio structure, energy and stable Cr isotopes equilibrium fractionation of some geochemically relevant H-O-Cr-Cl complexes

Ottonello

Zuccolini

2005

Geochimica et Cosmochimica Acta

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Coupling a polarizable water model to the hydrated ion–water interaction potential: A test on the Cr3+ hydration

Cited by 45 publications

References 67 publications

Structure and dynamics of the Cr(III) ion in aqueous solution: Ab initio QM/MM molecular dynamics simulation

Structure and dynamics of the Cr(III) ion in aqueous solution: Ab initio QM/MM molecular dynamics simulation

QM/MM: what have we learned, where are we, and where do we go from here?

Ab-initio structure, energy and stable Cr isotopes equilibrium fractionation of some geochemically relevant H-O-Cr-Cl complexes

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