Your search keyword '"Chewook Lee"' showing total 6 results

1. Nitrile and thiocyanate IR probes: Quantum chemistry calculation studies and multivariate least-square fitting analysis.

Author

Jun-Ho Choi, Kwang-Im Oh, Hochan Lee, Chewook Lee, and Minhaeng Cho

Subjects

NITRILES, THIOCYANATES, HYDRATION, MOLECULES, QUANTUM chemistry, VIBRATIONAL spectra, PHYSICAL & theoretical chemistry

Abstract

Hydration effects on the C=N stretching mode frequencies of MeCN and MeSCN are investigated by carrying out ab initio calculations for a number of MeCN-water and MeSCN-water complexes with varying number of water molecules. It is found that the CN frequency shift induced by the hydrogen-bonding interactions with water molecules originate from two different ways to form hydrogen bonds with the nitrogen atom of the CN group. Considering the MeCN- and MeSCN-water cluster calculation results as databases, we first examined the validity of vibrational Stark effect relationship between the CN frequency and the electric field component parallel to the CN bond and found no strong correlation between the two. However, taking into account of additional electric field vector components is a simple way to generalize the vibrational Stark theory for the nitrile chromophore. Also, the electrostatic potential calculation method has been proposed and examined in detail. It turned out that the interactions of water molecules with nitrogen atom’s lone pair orbital and with nitrile π orbitals can be well described by the electrostatic potential calculation method. The present computational results will be of use to quantitatively simulate various linear and nonlinear vibrational spectra of nitrile compounds in solutions. [ABSTRACT FROM AUTHOR]

Published

2008

2. Phenol-benzene complexation dynamics: Quantum chemistry calculation, molecular dynamics simulations, and two dimensional IR spectroscopy.

Author

Kijeong Kwac, Chewook Lee, Yousung Jung, Jaebeom Han, Kyungwon Kwak, Junrong Zheng, Fayer, M. D., and Minhaeng Cho

Subjects

*PHENOL, *BENZENE, *QUANTUM chemistry, *MOLECULAR dynamics, *INFRARED spectroscopy, *QUANTUM theory

Abstract

Molecular dynamics (MD) simulations and quantum mechanical electronic structure calculations are used to investigate the nature and dynamics of the phenol-benzene complex in the mixed solvent, benzene/CCl4. Under thermal equilibrium conditions, the complexes are continuously dissociating and forming. The MD simulations are used to calculate the experimental observables related to the phenol hydroxyl stretching mode, i.e., the two dimensional infrared vibrational echo spectrum as a function of time, which directly displays the formation and dissociation of the complex through the growth of off-diagonal peaks, and the linear absorption spectrum, which displays two hydroxyl stretch peaks, one for the complex and one for the free phenol. The results of the simulations are compared to previously reported experimental data and are found to be in quite reasonable agreement. The electronic structure calculations show that the complex is T shaped. The classical potential used for the phenol-benzene interaction in the MD simulations is in good accord with the highest level of the electronic structure calculations. A variety of other features is extracted from the simulations including the relationship between the structure and the projection of the electric field on the hydroxyl group. The fluctuating electric field is used to determine the hydroxyl stretch frequency-frequency correlation function (FFCF). The simulations are also used to examine the number distribution of benzene and CCl4 molecules in the first solvent shell around the phenol. It is found that the distribution is not that of the solvent mole fraction of benzene. There are substantial probabilities of finding a phenol in either a pure benzene environment or a pure CCl4 environment. A conjecture is made that relates the FFCF to the local number of benzene molecules in phenol’s first solvent shell. [ABSTRACT FROM AUTHOR]

Published

2006

3. Vibrational dynamics of DNA. III. Molecular dynamics simulations of DNA in water and theoretical calculations of the two-dimensional vibrational spectra.

Author

Chewook Lee, Kwang-Hee Park, Jin-A Kim, Seungsoo Hahn, and Minhaeng Cho

Subjects

*MOLECULAR dynamics, *NUCLEIC acids, *SPECTRUM analysis, *DENSITY functionals, *PARTICLES (Nuclear physics), *QUANTUM chemistry

Abstract

A theoretical description of the vibrational excitons in DNA is presented by using the vibrational basis mode theory developed in Papers I and II. The parameters obtained from the density functional theory calculations, such as vibrational coupling constants and basis mode frequencies, are used to numerically simulate two-dimensional (2D) IR spectra of dGn:dCn and dAn:dTn double helices with n varying from 1 to 10. From the molecular dynamics simulations of dG5C5 and dA5T5 double helices in D2O solution, it is found that the thermally driven internal motions of these systems in an aqueous solution do not induce strong fluctuations of basis mode frequencies nor vibrational couplings. In order to construct the two-exciton Hamiltonian, the vibrational anharmonicities of eight basis modes are obtained by carrying out B3LYP/6-31G* calculations for the nine basis modes. The simulated 2D IR spectra of dGn:dCn double helix in D2O solution are directly compared with closely related experimental results. The 2D IR spectra of dGn:dCn and dAn:dTn are found to be weakly dependent on the number of base pairs. The present work demonstrates that the computational procedure combining quantum chemistry calculation and molecular dynamics simulation methods can be of use to predict 2D IR spectra of nucleic acids in solutions. [ABSTRACT FROM AUTHOR]

Published

2006

4. Elucidating the Molecular Origin of Hydrolysis Energy of Pyrophosphate in Water

Author

Sihyun Ham, Song-Ho Chong, Fumio Hirata, Chewook Lee, Jooyeon Hong, and Norio Yoshida

Subjects

Physics::Biological Physics, Quantitative Biology::Biomolecules, Field (physics), Stereochemistry, Solvation, Ab initio, Quantum chemistry, Pyrophosphate, Computer Science Applications, Quantitative Biology::Subcellular Processes, Hydrolysis, chemistry.chemical_compound, chemistry, ATP hydrolysis, Computational chemistry, Intramolecular force, Physical and Theoretical Chemistry

Abstract

The molecular origin of the energy produced by the ATP hydrolysis has been one of the long-standing fundamental issues. A classical view is that the negative hydrolysis free energy of ATP originates from intramolecular effects connected with the backbone P-O bond, so called "high-energy bond". On the other hand, it has also been recognized that solvation effects are essential in determining the hydrolysis free energy. Here, using the 3D-RISM-SCF (three-dimensional reference interaction site model self-consistent field) theory that integrates the ab initio quantum chemistry method and the statistical mechanical theory of liquids, we investigate the molecular origin of hydrolysis free energy of pyrophosphate, an ATP analogue, in water. We demonstrate that our theory quantitatively reproduces the experimental results without the use of empirical parameters. We clarify the crucial role of water in converting the hydrolysis free energy in the gas phase determined solely by intramolecular effects, which ranges from endothermic, thermoneutral, to highly exothermic depending on the charged state of pyrophosphate, into moderately exothermic in the aqueous phase irrespective of the charged state as observed in experimental data. We elucidate that this is brought about by different natures of solute-water interactions depending on the charged state of solute species: the hydration free energy of low-charged state is mainly subjected to short-range hydrogen-bonds, while that of high-charged state is dominated by long-range electrostatic interactions. We thus provide unambiguous evidence on the critical role of water in determining the ATP hydrolysis free energy.

Published

2015

5. Amide I Modes of α-Helical Polypeptide in Liquid Water: Conformational Fluctuation, Phase Correlation, and Linear and Nonlinear Vibrational Spectra

Author

Chewook Lee, Sihyun Ham, Kyungwon Kwak, Seungsoo Hahn, Taekyung Kim, and Minhaeng Cho

Subjects

Coupling constant, Physics::Biological Physics, Quantitative Biology::Biomolecules, Liquid water, Chemistry, Molecular physics, Quantum chemistry, Surfaces, Coatings and Films, Nonlinear system, Delocalized electron, Molecular dynamics, Normal mode, Computational chemistry, Phase correlation, Materials Chemistry, Physical and Theoretical Chemistry

Abstract

Chain length and site dependencies of amide I local mode frequencies of α-helical polyalanines are theoretically studied by carrying out semiempirical quantum chemistry calculations. A theoretical model that can be used to quantitatively predict both the local amide I mode frequencies and coupling constants between two different local amide I modes is developed. Using this theoretical model and performing molecular dynamics simulation of an α-helical polyalanine in liquid water, we investigate conformational fluctuation and hydrogen-bonding dynamics by monitoring amide I frequency fluctuations. The instantaneous normal-mode analysis method is used to obtain densities of states of the one- and two-exciton bands and to quantitatively investigate the extent of delocalization of the instantaneous amide I normal modes. Also, by introducing a novel concept of the so-called weighted phase-correlation factor, the symmetric natures of the delocalized amide I normal modes are elucidated, and it is also shown that t...

Published

2004

6. Phenol-benzene complexation dynamics: quantum chemistry calculation, molecular dynamics simulations, and two dimensional IR spectroscopy

Author

Kijeong Kwac, Kyungwon Kwak, Yousung Jung, Minhaeng Cho, Chewook Lee, Jaebeom Han, Michael D. Fayer, and Junrong Zheng

Subjects

Models, Molecular, Absorption spectroscopy, Spectrophotometry, Infrared, Macromolecular Substances, Molecular Conformation, General Physics and Astronomy, Infrared spectroscopy, Electronic structure, Quantum chemistry, Molecular physics, chemistry.chemical_compound, Molecular dynamics, Physics::Atomic and Molecular Clusters, Vibrational energy relaxation, Computer Simulation, Physics::Chemical Physics, Physical and Theoretical Chemistry, Benzene, Carbon Tetrachloride, Phenol, chemistry, Models, Chemical, Chemical physics, Solvents, Quantum Theory, Density functional theory

Abstract

Molecular dynamics (MD) simulations and quantum mechanical electronic structure calculations are used to investigate the nature and dynamics of the phenol-benzene complex in the mixed solvent, benzene∕CCl4. Under thermal equilibrium conditions, the complexes are continuously dissociating and forming. The MD simulations are used to calculate the experimental observables related to the phenol hydroxyl stretching mode, i.e., the two dimensional infrared vibrational echo spectrum as a function of time, which directly displays the formation and dissociation of the complex through the growth of off-diagonal peaks, and the linear absorption spectrum, which displays two hydroxyl stretch peaks, one for the complex and one for the free phenol. The results of the simulations are compared to previously reported experimental data and are found to be in quite reasonable agreement. The electronic structure calculations show that the complex is T shaped. The classical potential used for the phenol-benzene interaction in the MD simulations is in good accord with the highest level of the electronic structure calculations. A variety of other features is extracted from the simulations including the relationship between the structure and the projection of the electric field on the hydroxyl group. The fluctuating electric field is used to determine the hydroxyl stretch frequency-frequency correlation function (FFCF). The simulations are also used to examine the number distribution of benzene and CCl4 molecules in the first solvent shell around the phenol. It is found that the distribution is not that of the solvent mole fraction of benzene. There are substantial probabilities of finding a phenol in either a pure benzene environment or a pure CCl4 environment. A conjecture is made that relates the FFCF to the local number of benzene molecules in phenol’s first solvent shell.

Published

2007