Your search keyword '"Jiu Zhao"' showing total 4 results

1. State-resolved dynamics study of the H + HS reaction on the ³A' and ³A'' states with time-dependent quantum wave packet method.

Author

Hui Wu, Zhi-Xin Duan, Shu-Hui Yin, and Guang-Jiu Zhao

Subjects

CHEMICAL reactions, TIME-dependent density functional theory, QUANTUM interference devices, WAVE packets, POTENTIAL energy surfaces, COLLISIONS (Physics), QUANTUM mechanics

Abstract

The quantum dynamics calculations of the H + HS (v = 0, j = 0) reaction on the ³A' and ³A'' potential energy surfaces (PESs) are performed using the reactant coordinate based time-dependent wave packet method. State-averaged and state-resolved results for both channels of the title reaction are presented in the 0.02-1.0 eV collision energy range and compared with those carried out with quasi-classical trajectory (QCT) method. Total integral cross sections (ICSs) for both channels are in excellent agreement with previous quantum mechanical (QM)-Coriolis coupling results while poorly agree with the QCT ICSs of the exchange channel, particularly near the threshold energy region. The product rotational distributions show that for the abstraction channel, the agreement between our QM and the QCT results improves with increasing collision energy. For the exchange channel, our calculations predict colder rotational distributions as compared to those obtained by QCT calculations. Although the QM total differential cross sections (DCSs) are in qualitatively good agreement with the QCT results, the two sets of the state-to-state DCSs with several peaks exhibit great divergences. The origin of the divergences are traced by analyzing the QM DCS for the H + HS (v = 0, j = 0) → H2 (v ' = 0, j' = 0) + S reaction on the ³A'' PES at Ec = 1.0 eV. It is discovered that several groups of J partial waves are involved in the reaction and the shape of the DCS is greatly altered by quantum interferences between them. [ABSTRACT FROM AUTHOR]

Published

2016

2. Non-adiabatic dynamics investigation of the radiationless decay mechanism of trans-urocanic acid in the S2 state.

Author

Li Zhao, Pan-Wang Zhou, and Guang-Jiu Zhao

Subjects

ADIABATIC processes, RADIATIONLESS deactivation, UROCANIC acid, CHROMOPHORES, ISOMERIZATION

Abstract

The trans-urocanic acid, a UV chromophore in the epidermis of human skin, was found to exhibit a wavelength dependent isomerization property. The isomerization quantum yield to cis-urocanic is greatest when being excited to the S1 state, whereas exciting the molecule to the S2 state causes almost no isomerization. The comparative photochemical behavior of the trans-urocanic on the S1 and S2 states continues to be the subject of intense research effort. This study is concerned with the unique photo-behavior of this interesting molecule on the S2 state. Combining the on-the-fly surface hopping dynamics simulations and static electronic structure calculations, three decay channels were observed following excitation to the S2 state. An overwhelming majority of the molecules decay to the S1 state through a planar or pucker characterized minimum energy conical intersection (MECI), and then decay to the ground state along a relaxation coordinate driven by a pucker deformation of the ring. A very small fraction of molecules decay to the S1 state by a MECI characterized by a twisting motion around the CC double bond, which continues to drive the molecule to deactivate to the ground state. The latter channel is related with the photoisomerization process, whereas the former one will only generate the original trans-form products. The present work provides a novel S2 state decay mechanism of this molecule, which offers useful information to explain the wavelength dependent isomerization behavior. [ABSTRACT FROM AUTHOR]

Published

2016

3. Ultrafast excited-state dynamics of tetraphenylethylene studied by semiclassical simulation.

Author

Guang-Jiu Zhao, Ke-Li Han, Yi-Bo Lei, and Yu-Sheng Dou

Subjects

*STYRENE, *SIMULATION methods & models, *EXCITED state chemistry, *PHOTOISOMERIZATION, *LASER beams

Abstract

Detailed simulation study is reported for the excited-state dynamics of photoisomerization of cis-tetraphenylethylene (TPE) following excitation by a femtosecond laser pulse. The technique for this investigation is semiclassical dynamics simulation, which is described briefly in the paper. Upon photoexcitation by a femtosecond laser pulse, the stretching motion of the ethylenic bond of TPE is initially excited, leading to a significant lengthening of ethylenic bond in 300 fs. Twisting motion about the ethylenic bond is activated by the energy released from the relaxation of the stretching mode. The 90° twisting about the ethylenic bond from an approximately planar geometry to nearly a perpendicular conformation in the electronically excited state is completed in 600 fs. The torsional dynamics of phenyl rings which is temporally lagging behind occurs at about 5 ps. Finally, the twisted TPE reverts to the initial conformation along the twisting coordinate through nonadiabatic transitions. The simulation results provide a basis for understanding several spectroscopic observations at molecular levels, including ultrafast dynamic Stokes shift, multicomponent fluorescence, viscosity dependence of the fluorescence lifetime, and radiationless decay from electronically excited state to the ground state along the isomerization coordinate. [ABSTRACT FROM AUTHOR]

Published

2007

4. Novel infrared spectra for intermolecular dihydrogen bonding of the phenol-borane-trimethylamine complex in electronically excited state.

Author

Guang-Jiu Zhao and Ke-Li Han

Subjects

*INFRARED spectra, *HYDROGEN bonding, *DENSITY functionals, *MOLECULAR dynamics, *CHEMICAL reactions, *ABSORPTION, *FLUORESCENCE

Abstract

The intermolecular dihydrogen bonding in the electronically excited states of the dihydrogen-bonded phenol-BTMA complex in gas phase was theoretically investigated using the time-dependent density functional theory method for the first time. It was theoretically demonstrated that the S1 state of the dihydrogen-bonded phenol-BTMA complex is a locally excited state, in which only the phenol moiety is electronically excited. The infrared spectra of the dihydrogen-bonded phenol-BTMA complex in ground state and the S1 state were calculated at both the O–H and B–H stretching vibrational regions. A novel infrared spectrum of the dihydrogen-bonded phenol-BTMA complex in the electronically excited state was found. The stretching vibrational absorption bands of the dihydrogen-bonded O–H and B–H groups are very strong in the ground state, while they are disappeared in the S1 state. At the same time, a new strong absorption band appears at the C==O stretching region. From the calculated bond lengths, it was found that both the O–H and B–H bonds in the dihydrogen bond O–H...H–B are significantly lengthened in the S1 state of the dihydrogen-bonded phenol-BTMA complex. However, the C–O bond in the phenol moiety is markedly shortened in the excited state, and then has the characteristics of C==O group. Furthermore, it was demonstrated that the intermolecular dihydrogen bonds in the electronically excited state of the dihydrogen-bonded phenol-BTMA complex are strengthened, since calculated H...H distance is drastically shortened in the S1 state. [ABSTRACT FROM AUTHOR]

Published

2007