Search

Your search keyword '"Hanasaki, Kota"' showing total 22 results
Start Over Author "Hanasaki, Kota"
22 results on '"Hanasaki, Kota"'

1. Implementation of real‐time TDDFT for periodic systems in the open‐source PySCF software package

Author

Hanasaki, Kota, Ali, Zulfikhar A, Choi, Min, Del Ben, Mauro, and Wong, Bryan M

Subjects
Chemical Sciences, Physical Chemistry, electron dynamics, electron transfer, Gaussian basis, periodic systems, photophysics, real-time time-dependent density functional theory, Physical Chemistry (incl. Structural), Theoretical and Computational Chemistry, Nanotechnology, Chemical Physics, Physical chemistry, Theoretical and computational chemistry
Abstract

We present a new implementation of real-time time-dependent density functional theory (RT-TDDFT) for calculating excited-state dynamics of periodic systems in the open-source Python-based PySCF software package. Our implementation uses Gaussian basis functions in a velocity gauge formalism and can be applied to periodic surfaces, condensed-phase, and molecular systems. As representative benchmark applications, we present optical absorption calculations of various molecular and bulk systems and a real-time simulation of field-induced dynamics of a (ZnO)4 molecular cluster on a periodic graphene sheet. We present representative calculations on optical response of solids to infinitesimal external fields as well as real-time charge-transfer dynamics induced by strong pulsed laser fields. Due to the widespread use of the Python language, our RT-TDDFT implementation can be easily modified and provides a new capability in the PySCF code for real-time excited-state calculations of chemical and material systems.

Published
2023

2. Spin current in the early stage of radical reactions and its mechanisms.

Author

Hanasaki, Kota and Takatsuka, Kazuo

Subjects
*RADICALS (Chemistry), *AB-initio calculations, *PERTURBATION theory, *CHEMICAL bonds, *FLUX flow
Abstract

We study the electronic spin flux (atomic-scale flow of the spin density in molecules) by a perturbation analysis and ab initio nonadiabatic calculations. We derive a general perturbative expression of the charge and spin fluxes and identify the driving perturbation of the fluxes to be the time derivative of the electron-nucleus interaction term in the Hamiltonian. We then expand the expression in molecular orbitals so as to identify relevant components of the fluxes. Our perturbation theory describes the electronic fluxes in the early stage of reactions in an intuitively clear manner. The perturbation theory is then applied to an analysis of the spin flux obtained in ab initio calculations of the radical reaction of O2 and CH3· starting from three distinct spin configurations; (a) CH3· and triplet O2 with total spin of the system set S t o t = 1 / 2 (b) CH3· and singlet O2, S t o t = 1 / 2 , and (c) CH3· and triplet O2, S t o t = 3 / 2. Further analysis of the time-dependent behaviors of the spin flux in these numerical simulations reveals (i) the spin flux induces rearrangement of the local spin structure, such as reduction of the spin polarization arising from the triplet O2 and (ii) the spin flux flows from O2 to CH3· in the reaction starting from spin configuration (a) and from CH3· to O2 in that starting from configuration (b), whereas no major intermolecular spin flux was observed in that starting from configuration (c). Our study thus establishes the mechanism of the spin flux that rearranges the local spin structures associated with chemical bonds. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

5. Efficient electronic structure calculation for molecular ionization dynamics at high x-ray intensity

Author

Hao, Yajiang, Inhester, Ludger, Hanasaki, Kota, Son, Sang-Kil, and Santra, Robin

Subjects
Physics - Chemical Physics, Physics - Computational Physics
Abstract

We present the implementation of an electronic-structure approach dedicated to ionization dynamics of molecules interacting with x-ray free-electron laser (XFEL) pulses. In our scheme, molecular orbitals for molecular core-hole states are represented by linear combination of numerical atomic orbitals that are solutions of corresponding atomic core-hole states. We demonstrate that our scheme efficiently calculates all possible multiple-hole configurations of molecules formed during XFEL pulses. The present method is suitable to investigate x-ray multiphoton multiple ionization dynamics and accompanying nuclear dynamics, providing essential information on the chemical dynamics relevant for high-intensity x-ray imaging., Comment: 28 pages, 6 figures

Published
2015
Full Text
View/download PDF

6. Fate of Quasiparticle at Mott Transition and Interplay with Lifshitz Transition Studied by Correlator Projection Method

Author

Hanasaki, Kota and Imada, Masatoshi

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Filling-control metal-insulator transition on the two-dimensional Hubbard model is investigated by using the correlator projection method, which takes into account momentum dependence of the free energy beyond the dynamical mean-field theory. The phase diagram of metals and Mott insulators is analyzed. Lifshitz transitions occur simultaneously with metal-insulator transitions at large Coulomb repulsion. On the other hand, they are separated each other for lower Coulomb repulsion, where the phase sandwiched by the Lifshitz and metal-insulator transitions appears to show violation of the Luttinger sum rule. Through the metal-insulator transition, quasiparticles retain nonzero renormalization factor and finite quasi-particle weight in the both sides of the transition. This supports that the metal-insulator transition is caused not by the vanishing renormalization factor but by the relative shift of the Fermi level into the Mott gap away from the quasiparticle band, in sharp contrast with the original dynamical mean-field theory. Charge compressibility diverges at the critical end point of the first-order Lifshitz transition at finite temperatures. The origin of the divergence is ascribed to singular momentum dependence of the quasiparticle dispersion., Comment: 24 pages including 10 figures

Published
2006
Full Text
View/download PDF

7. Charge Ordered Insulator without Magnetic Order Studied by Correlator Projection Method

Author

Hanasaki, Kota and Imada, Masatoshi

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

The Hubbard model with additional intersite interaction `$V$' (the extended Hubbard model) is investigated by the correlator projection method (CPM). CPM is a newly developed numerical method which combines the equation-of-motion approach and the dynamical mean-field theory. Using this method, properties of the extended Hubbard Model at quarter filling are discussed with special emphasis on the metal-insulator transition induced by electron-electron correlations. The result shows a metal-insulator transition to a charge ordered insulator with antiferromagnetic order at low temperatures, but a charge ordered insulator without magnetic symmetry breaking at intermediate temperatures. Here, the magnetic order is found to be suppressed to low temperatures because of the smallness of the exchange coupling $J_{\rm eff}$. The present results are in sharp contrast with the Hatree-Fock approximation whereas in agreement with the experimental results on quarter-filled materials with strong correlations, such as organic conductors., Comment: 28 pages, 8 figures

Published
2005
Full Text
View/download PDF

8. Front Cover

Author

Hanasaki, Kota, primary, Ali, Zulfikhar A., additional, Choi, Min, additional, Del Ben, Mauro, additional, and Wong, Bryan M., additional

Published
2023
Full Text
View/download PDF

10. On the molecular electronic flux: Role of nonadiabaticity and violation of conservation.

Author

Hanasaki, Kota and Takatsuka, Kazuo

Subjects
*FLUX (Energy), *CHEMICAL reactions, *MOLECULAR dynamics, *CONSERVATION laws (Physics)
Abstract

Analysis of electron flux within and in between molecules is crucial in the study of real-time dynamics of molecular electron wavepacket evolution such as those in attosecond laser chemistry and ultrafast chemical reaction dynamics. We here address two mutually correlated issues on the conservation law of molecular electronic flux, which serves as a key consistency condition for electron dynamics. The first one is about a close relation between "weak" nonadiabaticity and the electron dynamics in low-energy chemical reactions. We show that the electronic flux in adiabatic reactions can be consistently reproduced by taking account of nonadiabaticity. Such nonadiabaticity is usually weak in the sense that it does not have a major effect on nuclear dynamics, whereas it plays an important role in electronic dynamics. Our discussion is based on a nonadiabatic extension of the electronic wavefunction similar in idea to the complete adiabatic formalism developed by Nafie [J. Chem. Phys. 79, 4950 (1983)], which has also recently been reformulated by Patchkovskii [J. Chem. Phys. 137, 084109 (2012)]. We give straightforward proof of the theoretical assertion presented by Nafie using a time-dependent mixed quantum–classical framework and a standard perturbation expansion. Explicitly taking account of the flux conservation, we show that the nonadiabatically induced flux realizes the adiabatic time evolution of the electronic density. In other words, the divergence of the nonadiabatic flux equals the time derivative of the electronic density along an adiabatic time evolution of the target molecule. The second issue is about the accurate computationability of the flux. The calculation of flux needs an accurate representation of the (relative) quantum phase, in addition to the amplitude factor, of a total wavefunction and demands special attention for practical calculations. This paper is the first one to approach this issue directly and show how the difficulties arise explicitly. In doing so, we reveal that a number of widely accepted truncation techniques for static property calculations are potential sources of numerical flux non-conservation. We also theoretically propose alternative strategies to realize better flux conservation. [ABSTRACT FROM AUTHOR]

Published
2021
Full Text
View/download PDF

11. Molecular ionization enhancement by charge rearrangement at high X-ray intensity

Author

Inhester Ludger, Hanasaki Kota, Toyota Koudai, Hao Yajiang, Vendrell Oriol, Son Sang-Kil, and Santra Robin

Subjects
Physics, QC1-999
Abstract

We simulated the multi-photon multi-ionization dynamics of an iodomethane molecule, CH3I, exposed to ultraintense and ultrashort x-ray pulses. The strong ionization causes electronic charge rearrangement in the molecule that leads to an enhanced total charge.

Published
2019
Full Text
View/download PDF

12. Relativistic theory of electron-nucleus-radiation coupled dynamics in molecules: Wavepacket approach.

Author

Hanasaki, Kota and Takatsuka, Kazuo

Subjects
*TIME-dependent Schrodinger equations, *LASER-plasma interactions, *RELATIVISTIC electrons, *ULTRASHORT laser pulses, *DYNAMICS, *LASER pulses
Abstract

We propose a general theoretical scheme of relativistic electron-nucleus coupled dynamics of molecules in radiation fields, which is derived from quantum electrodynamical formalism. Aiming at applications to field-induced dynamics in ultrastrong laser pulses to the magnitude of 1016 W/cm2 or even larger, we derive a nonperturbative formulation of relativistic dynamics using the Tamm-Dancoff expansion scheme, which results in, within the lowest order expansion, a time-dependent Schrödinger equation with the Coulombic and retarded transversal photon-exchange interactions. We also discuss a wavepacket type nuclear dynamics adapted for such dynamics. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

13. An efficient approximate algorithm for nonadiabatic molecular dynamics.

Author

Hanasaki, Kota, Kanno, Manabu, Niehaus, Thomas A., and Kono, Hirohiko

Subjects
*APPROXIMATION algorithms, *ADIABATIC processes, *MOLECULAR dynamics, *EXCITED states, *POTENTIAL energy surfaces
Abstract

We propose a modification to the nonadiabatic surface hopping calculation method formulated in a paper by Yu et al. [Phys. Chem. Chem. Phys. 16, 25883 (2014)], which is a multidimensional extension of the Zhu-Nakamura theory with a practical diabatic gradient estimation algorithm. In our modification, their diabatic gradient estimation algorithm, which is based on a simple interpolation of the adiabatic potential energy surfaces, is replaced by an algorithm using the numerical derivatives of the adiabatic gradients. We then apply the algorithm to several models of nonadiabatic dynamics, both analytic and ab initio models, to numerically demonstrate that our method indeed widens the applicability and robustness of their method. We also discuss the validity and limitations of our new nonadiabatic surface hopping method while considering in mind potential applications to excited-state dynamics of biomolecules or unconventional nonadiabatic dynamics such as radiation decay processes in ultraintense X-ray fields. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

22. Fundamental Approaches to Nonadiabaticity: Toward a Chemical Theory beyond the Born — Oppenheimer Paradigm.

Author

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

Subjects
*ADIABATIC invariants, *BORN-Oppenheimer approximation, *MATHEMATICAL models, *QUANTUM theory, *CHEMICAL reactions, *CHARGE exchange, *QUANTUM perturbations
Abstract

The article focuses on the basic approaches to nonadiabatic transitions in electron dynamics. It states that nonadiabatic transitions were proposed to study occurrences in chemical reactions such as electron transfer among atoms. It discusses the perturbation theory, Born-Oppenheimer (BO) approximation, which can be used to study the existence of a molecule in a stable condition. Moreover, it provides examples of the mixed quantum and classical dynamics theory.

Published
2012
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results