Your search keyword '"Chewook Lee"' showing total 4 results

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

Author

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

Subjects

Nitrile, Hydrogen bond, Chemistry, Solvation, General Physics and Astronomy, Quantum chemistry, Molecular physics, symbols.namesake, chemistry.chemical_compound, Stark effect, Ab initio quantum chemistry methods, Molecular vibration, symbols, Molecule, Physics::Chemical Physics, Physical and Theoretical Chemistry, Atomic physics

Abstract

Hydration effects on the C[Triple Bond]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 pi 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.

Published

2008

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

Author

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

Subjects

Nucleotides, Chemistry, Water, General Physics and Astronomy, Infrared spectroscopy, DNA, Vibration, Hot band, symbols.namesake, Molecular dynamics, Models, Chemical, Vibrational partition function, Helix, symbols, Nucleic Acid Conformation, Computer Simulation, Density functional theory, Physics::Chemical Physics, Physical and Theoretical Chemistry, Atomic physics, Rotational–vibrational coupling, Hamiltonian (quantum mechanics), Base Pairing

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 dG(n):dC(n) and dA(n):dT(n) double helices with n varying from 1 to 10. From the molecular dynamics simulations of dG(5)C(5) and dA(5)T(5) double helices in D(2)O 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 B3LYP6-31G(*) calculations for the nine basis modes. The simulated 2D IR spectra of dG(n):dC(n) double helix in D(2)O solution are directly compared with closely related experimental results. The 2D IR spectra of dG(n):dC(n) and dA(n):dT(n) 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.

Published

2006

3. Vibrational dynamics of DNA. I. Vibrational basis modes and couplings

Author

Minhaeng Cho, Chewook Lee, and Kwang Hee Park

Subjects

Quantitative Biology::Biomolecules, Basis (linear algebra), Nucleotides, Chemistry, General Physics and Astronomy, DNA, Vibration, Hot band, Nucleobase, Delocalized electron, Models, Chemical, Vibrational partition function, Normal mode, Nucleic Acid Conformation, Computer Simulation, Density functional theory, Physical and Theoretical Chemistry, Atomic physics, Rotational–vibrational coupling, Base Pairing

Abstract

Carrying out density functional theory calculations of four DNA bases, base derivatives, Watson-Crick (WC) base pairs, and multiple-layer base pair stacks, we studied vibrational dynamics of delocalized modes with frequency ranging from 1400 to 1800 cm(-1). These modes have been found to be highly sensitive to structure fluctuation and base pair conformation of DNA. By identifying eight fundamental basis modes, it is shown that the normal modes of base pairs and multilayer base pair stacks can be described by linear combinations of these vibrational basis modes. By using the Hessian matrix reconstruction method, vibrational coupling constants between the basis modes are determined for WC base pairs and multilayer systems and are found to be most strongly affected by the hydrogen bonding interaction between bases. It is also found that the propeller twist and buckle motions do not strongly affect vibrational couplings and basis mode frequencies. Numerically simulated IR spectra of guanine-cytosine and adenine-thymine bases pairs as well as of multilayer base pair stacks are presented and described in terms of coupled basis modes. It turns out that, due to the small interlayer base-base vibrational interactions, the IR absorption spectrum of multilayer base pair system does not strongly depend on the number of base pairs.

Published

2006

4. Characteristic two-dimensional IR spectroscopic features of antiparallel and parallel β-sheet polypeptides: Simulation studies

Author

Minhaeng Cho, Seong Soo Kim, Chewook Lee, and Seungsoo Hahn

Subjects

Models, Molecular, Magnetic Resonance Spectroscopy, Spectrophotometry, Infrared, Protein Conformation, Diagonal, Molecular Conformation, Beta sheet, General Physics and Astronomy, Infrared spectroscopy, Antiparallel (biochemistry), Molecular physics, Protein Structure, Secondary, Delocalized electron, Nuclear magnetic resonance, Computer Simulation, Physical and Theoretical Chemistry, Spectroscopy, Photons, Models, Statistical, Chemistry, Proteins, Dipole, Models, Chemical, Spectrophotometry, Molecular vibration, Quantum Theory, Peptides

Abstract

The antiparallel and parallel beta sheets are two of the most abundant secondary structures found in proteins. Although various spectroscopic methods have been used to distinguish these two different structures, the linear spectroscopic measurements could not provide incisive information for distinguishing an antiparallel beta sheet from a parallel beta sheet. After carrying out quantum-chemistry calculations and model simulations, we show that the polarization-controlled two-dimensional (2D) IR photon echo spectroscopy can be of critical use in distinguishing these two different beta sheets. Particularly, the ratio between the diagonal peak and the cross peak is found to be strongly dependent on the quasi-2D array of the amide I local-mode transition dipole vectors. The relative intensities of the cross peaks in the 2D difference spectrum of an antiparallel beta sheet are significantly larger than those of the diagonal peaks, whereas the cross-peak amplitudes in the 2D difference spectrum of a parallel beta sheet are much weaker than the main diagonal-peak amplitudes. A detailed discussion on the origin of the diagonal- and cross-peak intensity distributions of both the antiparallel and parallel beta sheets is presented by examining vibrational exciton delocalization, relative angles between two different normal-mode transition dipoles, and natures of the cross peaks in the 2D difference spectrum.

Published

2005