lithium-chloride and lithium-fluoride

lithium-chloride has been researched along with lithium-fluoride* in 2 studies

Other Studies

2 other study(ies) available for lithium-chloride and lithium-fluoride

Article	Year
Theoretical studies on identity S(N)2 reactions of lithium halide and methyl halide: a microhydration model. Journal of molecular modeling, 2010, Volume: 16, Issue:12 Reactions of lithium halide (LiX, X = F, Cl, Br and I) and methyl halide (CH₃X, X = F, Cl, Br and I) have been investigated at the B3LYP/6-31G(d) level of theory using the microhydration model. Beginning with hydrated lithium ion, four or two water molecules have been conveniently introduced to these aqueous-phase halogen-exchange S(N)2 reactions. These water molecules coordinated with the center metal lithium ion, and also interacted with entering and leaving halogen anion via hydrogen bond in complexes and transition state, which to some extent compensated hydration of halogen anion. At 298 K the reaction profiles all involve central barriers ΔE ( cent ) which are found to decrease in the order F > Cl > Br > I. The same trend is also found for the overall barriers (ΔE(ovr)) of the title reaction. In the S(N)2 reaction of sodium iodide and methyl iodide, the activation energy agrees well with the aqueous conductometric investigation. Topics: Anions; Bromides; Computer Simulation; Fluorides; Hydrocarbons, Brominated; Hydrocarbons, Fluorinated; Hydrocarbons, Halogenated; Hydrocarbons, Iodinated; Hydrogen Bonding; Lithium Chloride; Lithium Compounds; Methyl Chloride; Models, Chemical; Models, Molecular; Molecular Conformation; Molecular Structure; Thermodynamics; Water	2010
Complete basis set extrapolated potential energy, dipole, and polarizability surfaces of alkali halide ion-neutral weakly avoided crossings with and without applied electric fields. The Journal of chemical physics, 2004, May-01, Volume: 120, Issue:17 Complete basis set extrapolations of alkali halide (LiF, LiCl, NaF, NaCl) energy, dipole, and polarizability surfaces are performed with and without applied fields along the internuclear axis using state-averaged multireference configuration interaction. Comparison between properties (equilibrium separation, dissociation energy, crossing distance, diabatic coupling constant, dipole, and polarizability) derived from the extrapolated potential energy (or dipole) surfaces are made with those obtained from direct extrapolation from the basis set trends. The two extrapolation procedures are generally found to agree well for these systems. Crossing distances from this work are compared to those of previous work and values obtained from the Rittner potential. Complete basis set extrapolated crossing distances agree well with those derived from the Rittner potential for LiF, but were significantly larger for LiCl, NaF, and NaCl. The results presented here serve as an important set of benchmark data for the development of new-generation many-body force fields that are able to model charge transfer. Topics: Chemistry, Physical; Electricity; Fluorides; Ions; Lithium Chloride; Lithium Compounds; Models, Statistical; Sodium Chloride; Sodium Fluoride	2004

Article

Year

Theoretical studies on identity S(N)2 reactions of lithium halide and methyl halide: a microhydration model.

Journal of molecular modeling, 2010, Volume: 16, Issue:12

Reactions of lithium halide (LiX, X = F, Cl, Br and I) and methyl halide (CH₃X, X = F, Cl, Br and I) have been investigated at the B3LYP/6-31G(d) level of theory using the microhydration model. Beginning with hydrated lithium ion, four or two water molecules have been conveniently introduced to these aqueous-phase halogen-exchange S(N)2 reactions. These water molecules coordinated with the center metal lithium ion, and also interacted with entering and leaving halogen anion via hydrogen bond in complexes and transition state, which to some extent compensated hydration of halogen anion. At 298 K the reaction profiles all involve central barriers ΔE ( cent ) which are found to decrease in the order F > Cl > Br > I. The same trend is also found for the overall barriers (ΔE(ovr)) of the title reaction. In the S(N)2 reaction of sodium iodide and methyl iodide, the activation energy agrees well with the aqueous conductometric investigation.

Topics: Anions; Bromides; Computer Simulation; Fluorides; Hydrocarbons, Brominated; Hydrocarbons, Fluorinated; Hydrocarbons, Halogenated; Hydrocarbons, Iodinated; Hydrogen Bonding; Lithium Chloride; Lithium Compounds; Methyl Chloride; Models, Chemical; Models, Molecular; Molecular Conformation; Molecular Structure; Thermodynamics; Water

2010

Complete basis set extrapolated potential energy, dipole, and polarizability surfaces of alkali halide ion-neutral weakly avoided crossings with and without applied electric fields.

The Journal of chemical physics, 2004, May-01, Volume: 120, Issue:17

Complete basis set extrapolations of alkali halide (LiF, LiCl, NaF, NaCl) energy, dipole, and polarizability surfaces are performed with and without applied fields along the internuclear axis using state-averaged multireference configuration interaction. Comparison between properties (equilibrium separation, dissociation energy, crossing distance, diabatic coupling constant, dipole, and polarizability) derived from the extrapolated potential energy (or dipole) surfaces are made with those obtained from direct extrapolation from the basis set trends. The two extrapolation procedures are generally found to agree well for these systems. Crossing distances from this work are compared to those of previous work and values obtained from the Rittner potential. Complete basis set extrapolated crossing distances agree well with those derived from the Rittner potential for LiF, but were significantly larger for LiCl, NaF, and NaCl. The results presented here serve as an important set of benchmark data for the development of new-generation many-body force fields that are able to model charge transfer.

Topics: Chemistry, Physical; Electricity; Fluorides; Ions; Lithium Chloride; Lithium Compounds; Models, Statistical; Sodium Chloride; Sodium Fluoride

2004