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Your search keyword '"Takehiro Yonehara"' showing total 7 results
Start Over Author "Takehiro Yonehara" Topic born-oppenheimer approximation
7 results on '"Takehiro Yonehara"'

1. Nonadiabtic electron dynamics in densely quasidegenerate states in highly excited boron cluster.

Author

Takehiro Yonehara and Kazuo Takatsuka

Subjects
*QUANTUM theory, *BORN-Oppenheimer approximation, *ELECTRONIC structure, *BORON, *MICROCLUSTERS, *EXCITED states
Abstract

Following the previous study on nonadiabatic reaction dynamics including boron clusters [T. Yonehara and K. Takatsuka, J. Chem. Phys. 137, 22A520 (2012)], we explore deep into highly excited electronic states of the singlet boron cluster (B12) to find the characteristic features of the densely quasi-degenerate electronic state manifold, which undergo very frequent nonadiabatic transitions and thereby intensive electronic state mixing among very many of the relevant states. So much so, isolating the individual adiabatic states and tracking the expected potential energy surfaces both lose the physical sense. This domain of molecular situation is far beyond the realm of the Born- Oppenheimer approximation. To survey such a violent electronic state-mixing, we apply a method of nonadiabatic electron wavepacket dynamics, the semiclassical Ehrenfest method. We have tracked those electron wavepackets and found the electronic state mixing looks like an ultrafast diffusion in the Hilbert space, which results in huge fluctuation. Furthermore, due to such a violent mixing, the quantum phases associated with the electronic states are swiftly randomized, and consequently the coherence among the electronic states are lost quickly. Besides, these highly excited states are mostly of highly poly-radical nature, even in the spin singlet manifold and the number of radicals amounts up to 10 electrons in the sense of unpaired electrons. Thus the electronic states are summarized to be poly-radical and decoherent with huge fluctuation in shorter time scales of vibrational motions. The present numerical study sets a theoretical foundation for unknown molecular properties and chemical reactivity of such densely quasi-degenerate chemical species. [ABSTRACT FROM AUTHOR]

Published
2016
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2. Proton dynamics in crystalline tropolone studied by Born-Oppenheimer molecular simulations

Author

Takahito Nakajima, Mateusz Z. Brela, Marek Boczar, Marek J. Wójcik, Yukihiro Ozaki, Łukasz J. Witek, and Takehiro Yonehara

Subjects
Materials science, 010304 chemical physics, Hydrogen bond, Dimer, Born–Oppenheimer approximation, General Physics and Astronomy, Conjugated system, 010402 general chemistry, 01 natural sciences, Tropolone, 0104 chemical sciences, Crystal, Molecular dynamics, Crystallography, Quantization (physics), chemistry.chemical_compound, symbols.namesake, chemistry, 0103 physical sciences, symbols, Physical and Theoretical Chemistry
Abstract

Proton dynamics in a tropolone crystal was studied by 2D quantization of nuclear motions using Born-Oppenheimer molecular dynamics. This study presents the characteristics of the conjugated system of O H stretching vibrations in the tropolone crystal. The MD simulations elucidate the presence of a pseudo-cyclic dimer structure in the crystal phase. The results obtained herein were compared with the IR spectroscopic data for the tropolone crystal. The skeleton and butterfly motions of the seven carbon rings strongly influence the strength of the hydrogen bonds in the cyclic dimers and are extensively discussed in this paper.

Published
2018

3. Chemical Theory Beyond The Born-oppenheimer Paradigm: Nonadiabatic Electronic And Nuclear Dynamics In Chemical Reactions

Author

Kazuo Takatsuka, Yasuki Arasaki, Takehiro Yonehara, Kota Hanasaki, Kazuo Takatsuka, Yasuki Arasaki, Takehiro Yonehara, and Kota Hanasaki

Subjects
Born-Oppenheimer approximation, Chemical reactions, Charge exchange
Abstract

This unique volume offers a clear perspective of the relevant methodology relating to the chemical theory of the next generation beyond the Born-Oppenheimer paradigm. It bridges the gap between cutting-edge technology of attosecond laser science and the theory of chemical reactivity. The essence of this book lies in the method of nonadiabatic electron wavepacket dynamic, which will set a new foundation for theoretical chemistry.In light of the great progress of molecular electronic structure theory (quantum chemistry), the authors show a new direction towards nonadiabatic electron dynamics, in which quantum wavepackets have been theoretically and experimentally revealed to bifurcate into pieces due to the strong kinematic interactions between electrons and nuclei.The applications range from nonadiabatic chemical reactions in photochemical dynamics to chemistry in densely quasi-degenerated electronic states that largely fluctuate through their mutual nonadiabatic couplings. The latter is termed as “chemistry without the potential energy surfaces” and thereby virtually no theoretical approach has been made yet.Restarting from such a novel foundation of theoretical chemistry, the authors cast new light even on the traditional chemical notions such as the Pauling resonance theory, proton transfer, singlet biradical reactions, and so on.

Published
2015

6. Non-Born-Oppenheimer quantum chemistry on the fly with continuous path branching due to nonadiabatic and intense optical interactions

Author

Kazuo Takatsuka and Takehiro Yonehara

Subjects
Electromagnetic field, Chemistry, Wave packet, Attosecond, Born–Oppenheimer approximation, General Physics and Astronomy, Electron, Vibronic coupling, symbols.namesake, Quantization (physics), Quantum mechanics, Physics::Atomic and Molecular Clusters, symbols, Physics::Atomic Physics, Physics::Chemical Physics, Physical and Theoretical Chemistry, Vector potential
Abstract

We extend our formerly proposed theory for non-Born-Oppenheimer electronic and nuclear wavepacket dynamics within on-the-fly scheme [T. Yonehara, S. Takahashi, and K. Takatsuka, J. Chem. Phys. 130, 214113 (2009)] to a case of nonadiabatic dynamics under an intense laser field: electron wavepacket in a molecule is propagated in attosecond time-scale along non-Born-Oppenheimer nuclear paths that smoothly branch due to nonadiabatic coupling and/or optical interactions. Such branching paths are determined consistently with the motion of the electron wavepackets. Furthermore, these nuclear paths are quantized in terms of Gaussian wavepackets (action decomposed function), which can be applied to nonclassical paths. Both electronic wavepacket dynamics and quantization of non-Born-Oppenheimer paths are generalized so as to include the direct effects of the classical vector potential of electromagnetic fields. In the second half of this paper, we perform numerical studies to explore nonadiabatic dynamics in a laser field by examining two cases: one is a two-state model system having an avoided crossing, and the other is two-state dynamics in HF molecule on the two low lying ab initio potential curves. Both are placed in laser fields. With the former system, we survey some basic properties of the coupling of nonadiabatic dynamics and laser interaction varying the relevant coupling parameters such as the laser timing with respect to the incident of nonadiabatic transition. This investigation will set a foundation for the future studies of control of electronic states in realistic multidimensional molecular systems. Application to the latter system shows that non-Born-Oppenheimer quantum chemistry in laser fields is indeed useful in the study of dynamics in ab initio level. Through the comparison with full quantum data, we verify that the formalism and methodology developed here work accurately. Furthermore, we attain some basic insight about the characteristics of molecules in laser fields.

Published
2010

7. Non-Born-Oppenheimer electronic and nuclear wavepacket dynamics

Author

Kazuo Takatsuka, Satoshi Takahashi, and Takehiro Yonehara

Subjects
Physics, Quantum discord, Quantum dynamics, Born–Oppenheimer approximation, General Physics and Astronomy, Semiclassical physics, Open quantum system, Quantization (physics), symbols.namesake, Quantum mechanics, Quantum process, Physics::Atomic and Molecular Clusters, symbols, Physical and Theoretical Chemistry, Quantum dissipation
Abstract

A practical quantum theory for unifying electronic and nuclear dynamics, which were separated by the Born–Oppenheimer approximation, is proposed. The theory consists of two processes. Nonadiabatic (quantum) electron wavepacket dynamics on branching (non-Born–Oppenheimer) nuclear paths are first constructed. Since these paths are not the classical trajectories, most of the existing semiclassical theories to generate quantum wavepacket do not work. Therefore, we apply our own developed semiclassical wavepacket theory to these generated non-Born–Oppenheimer paths. This wavepacket is generated based on what we call the action decomposed function, which does not require the information of the so-called stability matrix. Thus, the motion of nuclei is also quantized, and consequently the total wave function is represented as a series of entanglement between the electronic and nuclear wavepackets. In the last half of the article, we show the practice to demonstrate how these independent theories can be unified to give electron-nuclear wavepackets in a two-state model. The wavepackets up to the phases and resultant transition probabilities are compared to the full quantum-mechanical counterparts. It turns out that the lowest level approximation to the wavepacket approach already shows a good agreement with the full quantum quantities. Thus, the present theoretical framework gives a basic method with which to study non-Born–Oppenheimer electronic and nuclear wavepacket states relevant to ultrafast chemical events.

Published
2009

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