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Author: Jeffrey Albert Draves Publisher: ISBN: Category : Languages : en Pages : 338
Book Description
The solvation of the alkali ions Na$sp{+}$ and Cs$sp{+}$ by methanol has been investigated by gas-phase vibrational spectroscopy and Monte Carlo simulations of small ion clusters: Na(CH$sb3$OH) $sbsp{rm N}{+}$, N = 6 to 15 and Cs(CH$sb3$OH) $sbsp{rm N}{+}$, N = 4 to 25. The solvated ions, generated by combining a thermionic alkali ion source with a molecular beam source, have considerable amounts of internal energy. The excess energy is dissipated by evaporation. The quasi-stable cluster ions are mass-selected for vibrational predissociation spectroscopy. The spectra are collected using a line-tunable cw-CO$sb2$ laser. Vibrational spectra indicate that the first solvation shell about the Na$sp{+}$ consists of six methanols while that about the Cs$sp{+}$ consists of ten. Large clusters of Cs(CH$sb3$OH) $sbsp{rm N}{+}$ (N $geq$ 18) appear to have small clusters of methanol bound to the surface of the solvated ion. Na(CH$sb3$OH) $sbsp{rm N}{+}$ clusters appear to have two structurally enhanced regions, i.e. a first and a second solvation shell. Monte Carlo simulations using pairwise interaction potentials were run at temperatures between 200 K and 300 K for the solvated ions Na(CH$sb3$OH) $sbsp{rm N}{+}$, N = 6-8, 10, 12, 15, and 25, and for Cs(CH$sb3$OH) $sbsp{rm N}{+}$, N = 6-16, and 25. Simulation results show the first solvation shell of Na$sp{+}$ and Cs$sp{+}$ is filled by 6.2 and 10.5 methanols, respectively. These numbers are consistent with experimental results. The simulations also indicate that hydrogen bonding plays a significant role in shaping the solvent shell structure for both species. Once the first solvation shell is filled, the size of the solvent shell appears to be independent of additional solvent molecules. After N = 6 for Na(CH$sb3$OH) $sbsp{rm N}{+}$, and N = 10 for Cs(CH$sb3$OH) $sbsp{rm N}{+}$ methanols begin entering the second solvent region, this shell is not filled before methanols enter the third solvent region. This is an indication of the extent to which the ion influences the solvating methanols. Gas-phase solvated ions appear to be useful models for dilute electolyte solutions. This technique produces solvated ions which exhibit several solvent regions. With the combination of the Monte Carlo simulations and vibrational spectroscopy, a clear picture of the solvation shell structure can be obtained.
Author: Jeffrey Albert Draves Publisher: ISBN: Category : Languages : en Pages : 338
Book Description
The solvation of the alkali ions Na$sp{+}$ and Cs$sp{+}$ by methanol has been investigated by gas-phase vibrational spectroscopy and Monte Carlo simulations of small ion clusters: Na(CH$sb3$OH) $sbsp{rm N}{+}$, N = 6 to 15 and Cs(CH$sb3$OH) $sbsp{rm N}{+}$, N = 4 to 25. The solvated ions, generated by combining a thermionic alkali ion source with a molecular beam source, have considerable amounts of internal energy. The excess energy is dissipated by evaporation. The quasi-stable cluster ions are mass-selected for vibrational predissociation spectroscopy. The spectra are collected using a line-tunable cw-CO$sb2$ laser. Vibrational spectra indicate that the first solvation shell about the Na$sp{+}$ consists of six methanols while that about the Cs$sp{+}$ consists of ten. Large clusters of Cs(CH$sb3$OH) $sbsp{rm N}{+}$ (N $geq$ 18) appear to have small clusters of methanol bound to the surface of the solvated ion. Na(CH$sb3$OH) $sbsp{rm N}{+}$ clusters appear to have two structurally enhanced regions, i.e. a first and a second solvation shell. Monte Carlo simulations using pairwise interaction potentials were run at temperatures between 200 K and 300 K for the solvated ions Na(CH$sb3$OH) $sbsp{rm N}{+}$, N = 6-8, 10, 12, 15, and 25, and for Cs(CH$sb3$OH) $sbsp{rm N}{+}$, N = 6-16, and 25. Simulation results show the first solvation shell of Na$sp{+}$ and Cs$sp{+}$ is filled by 6.2 and 10.5 methanols, respectively. These numbers are consistent with experimental results. The simulations also indicate that hydrogen bonding plays a significant role in shaping the solvent shell structure for both species. Once the first solvation shell is filled, the size of the solvent shell appears to be independent of additional solvent molecules. After N = 6 for Na(CH$sb3$OH) $sbsp{rm N}{+}$, and N = 10 for Cs(CH$sb3$OH) $sbsp{rm N}{+}$ methanols begin entering the second solvent region, this shell is not filled before methanols enter the third solvent region. This is an indication of the extent to which the ion influences the solvating methanols. Gas-phase solvated ions appear to be useful models for dilute electolyte solutions. This technique produces solvated ions which exhibit several solvent regions. With the combination of the Monte Carlo simulations and vibrational spectroscopy, a clear picture of the solvation shell structure can be obtained.
Author: Michael T. Bowers Publisher: Academic Press ISBN: 1483216497 Category : Science Languages : en Pages : 363
Book Description
Gas Phase Ion Chemistry, Volume 2 covers the advances in gas phase ion chemistry. The book discusses the stabilities of positive ions from equilibrium gas-phase basicity measurements; the experimental methods used to determine molecular electron affinities, specifically photoelectron spectroscopy, photodetachment spectroscopy, charge transfer, and collisional ionization; and the gas-phase acidity scale. The text also describes the basis of the technique of chemical ionization mass spectrometry; the energetics and mechanisms of unimolecular reactions of positive ions; and the photodissociation of gas-phase ions. The applications of molecular beam techniques to the study of ion-molecule collisions; as well as the variational treatment of charge transfer reactions are also encompassed. Chemists and biochemists will find the book invaluable.
Author: Ryan Patrick Dain Publisher: ISBN: Category : Electronic dissertations Languages : en Pages : 76
Book Description
A combination of theoretical chemistry and "action" spectroscopy has become the most used tool for the exploration of gas-phase molecular ions. In this study, density functional theory (DFT) calculations were used to test the validity of conclusions drawn from the results of a matrix-isolation infrared (MI-IR) experiment and develop a modeling method that could be used for metal-coordinating chlorate ion pairs. That modeling method was then used in comparison with experimental infrared multiple photon dissociation (IRMPD) spectroscopy to determine the structures of metal-chlorate anions. In addition to structural information, the effect of the modeling method on spectral correlation was also investigated.
Author: Jeffrey Albert Draves
Author: Jeffrey Albert Draves
Author: 
Author: American Chemical Society. Committee on Professional Training
Author: Michael T. Bowers
Author: 
Author: Sandra Enid Rodriguez-Cruz
Author: Jeremy Thomas O'Brien
Author: Nicholas Leo Pivonka
Author: Ryan Patrick Dain
Author: Xuegeng Li