Your search keyword '"Molecular orbital tomography"' showing total 4 results

1. Molecular orbital tomography of HOMO and HOMO-1 of the nonlinear molecule H2O: The study on multi-orbital effects

Author

Zhongxue Ren, Bin Zhang, Yan Yang, Yalei Zhu, Jing Zhao, and Zengxiu Zhao

Subjects

Molecular orbital tomography, High-order harmonic generation, H2O molecule, Multi-orbital effects, Physics, QC1-999

Abstract

Molecular orbital tomography (MOT) through high-order harmonic generation (HHG) is a crucial method for probing individual molecular orbitals. Previous studies mainly focused on linear molecules such as N2, and CO, where valence orbitals were imaged by detecting harmonic emission at various alignments. In this study, we investigate the HHG from the water molecules, with the aim of exploring MOT for nonlinear molecules. By employing the time-dependent density functional theory, we obtain HHG spectra for different angles between the laser polarization and molecular symmetry axis. By manipulating the scanning planes (planes perpendicular to the laser propagation direction and contain the field polarization direction), specific orbitals can be selectively imaged. Particularly, a well-reconstructed highest occupied molecular orbital (HOMO) is obtained when the laser scanning plane approximately aligns with the nodal plane of HOMO-1. However, when the laser polarization deviates from the nodal plane, multiple orbitals contribute to the HHG process, and we visualize the orbital distortions resulting from such effects. Furthermore, HOMO-1, can be reconstructed when the laser scanning plane aligns with the nodal plane of HOMO. This research significantly advances the development of MOT and opens up intriguing possibilities for reconstructing orbitals of more complex molecules.

Published

2023

2. SLIMP 2.0: A new version of strong laser interaction model package for atoms and molecules, now with molecular orbital tomography based on high-order harmonic spectra.

Author

Ren, Zhongxue, Zhang, Bin, Yang, Yan, Zhu, Yalei, Bai, Guangru, Liu, Jinlei, Zhao, Jing, and Zhao, Zengxiu

Subjects

*MOLECULAR orbitals, *ATOMIC models, *TOMOGRAPHY, *THREE-dimensional imaging, *GRAPHICAL projection

Abstract

A new version of strong laser interaction model package for atoms and molecules is presented. Its capacities are enhanced by incorporating modules related to molecular orbital tomography (MOT) in length and velocity forms based on high-order harmonic spectra (HHS). This advanced package enables two-dimensional and three-dimensional MOT of both symmetric and asymmetric molecules using HHS, providing an efficient means for both experimental and theoretical investigations of molecular orbital structures. In addition, it can calculate the precise theoretical orbitals corresponding to those reconstructed by MOT. Furthermore, the package can calculate the transition dipole moment (TDM) in the plane wave approximation and allow for reference MOT based on TDM. It can evaluate the quality of reconstructed orbitals based on HHS and reveal the physical and numerical effects on MOT. This package is suitable for MOT under conditions of driving laser at different intensities and wavelengths, and can be applied to different molecules with various structures. It is designed to facilitate easy expansion for additional capabilities. Program Title: SLIMP, version 2.0 CPC Library link to program files: https://doi.org/10.17632/jgcb7m7wwv.1 Licensing provisions: GPLv3 Programming language: Fortran 90 Journal reference of previous version: Comput. Phys. Commun. 192 (2015) 330-341. Does the new version supersede the previous version?: Yes. Reasons for the new version: Molecular orbital tomography (MOT) [1] based on high-order harmonic spectra (HHS) [2] is an important research topic in the field of strong-field physics. It provides an efficient way to probe molecular orbital structures experimentally, which was not considered in the former version of SLIMP [3] and is now included in SLIMP 2.0. The new version package allows performing two-dimensional (2D) and three-dimensional (3D) MOT [4] based on HHS obtained from experiments or simulations, providing reliable detections for many orbitals of interest, either symmetric or asymmetric molecules. Summary of revisions: Extending capacities focus on enabling performing 2D and 3D MOT on symmetric and asymmetric molecules based on HHS, and together the relevantly precise theoretical orbital output, calculation of transition dipole moment (TDM) and reference MOT based on TDM. For 2D MOT, MOT in both length and velocity forms are implemented. Nature of problem: To perform MOT based on HHS, the user needs general reconstruction programs, taking symmetric and asymmetric molecules, 2D and 3D orbitals, and MOT in length and velocity forms into account. In addition, evaluation of imaging quality is required, which can reveal the physical and numerical effects on reconstructions. Solution method: The 2D symmetric and asymmetric, length- and velocity-form, and 3D reconstruction algorithms are implemented based on Fortran 90. Furthermore, this package provides a reference MOT based on directly calculated TDM, served as a comparable result to the reconstructed orbital based on HHS. The comparison between reconstructions based on HHS and TDM can reveal the effects on MOT in physical and numerical aspects. Additional comments including restrictions and unusual features: This package does not include MOT of asymmetric molecules in velocity form. For the 2D MOT based on HHS, the reconstructed 2D projection of gerade, ungerade orbital or the gerade and ungerade components of asymmetric orbital must have the axial symmetry about the x - and z -axis. For the 3D MOT, the reconstructed 3D orbital has to be cylindrically symmetric. [1] J. Itatani, J. Levesque, D. Zeidler, H. Niikura, H. Pépin, J.-C. Kieffer, P. B. Corkum, D. M. Villeneuve, Tomographic imaging of molecular orbitals, Nature 432 (7019) (2004) 867–871. [2] M. Ferray, A. L'Huillier, X. F. Li, L. A. Lompre, G. Mainfray, C. Manus, Multiple-harmonic conversion of 1064 nm radiation in rare gases, J. Phys., B At. Mol. Opt. Phys. 21 (3) (1988) L31-L35. [3] B. Zhang, Z. Zhao, SLIMP: Strong laser interaction model package for atoms and molecules, Comput. Phys. Commun. 192 (2015) 330-341. [4] Z. Ren, Y. Yang, Y. Zhu, X. Zan, J. Zhao, Z. Zhao, Three-dimensional tomographic imaging of CO molecular orbitals reveals multi-electron effects, J. Phys., B At. Mol. Opt. Phys. 54 (18) (2021) 185601. • SLIMP 2.0 includes all the functions of the previous version, with added molecular orbital tomography (MOT). • It can export 3D and 2D projections of orbitals and compute transition dipole moment (TDM) in plane wave approximation. • SLIMP 2.0 can perform MOT based on high-order harmonic spectra from experiments or simulations or directly calculated TDM. • SLIMP 2.0 can perform 2D, length- and velocity-form, symmetric and asymmetric, and 3D MOT. • SLIMP 2.0 can perform MOT based on TDM to evaluate MOT quality and reveal physical and numerical effects on real MOT. [ABSTRACT FROM AUTHOR]

Published

2024

3. Molecular orbital tomography of HOMO and HOMO-1 of the nonlinear molecule H2O: The study on multi-orbital effects.

Author

Ren, Zhongxue, Zhang, Bin, Yang, Yan, Zhu, Yalei, Zhao, Jing, and Zhao, Zengxiu

Abstract

Molecular orbital tomography (MOT) through high-order harmonic generation (HHG) is a crucial method for probing individual molecular orbitals. Previous studies mainly focused on linear molecules such as N 2 , and CO, where valence orbitals were imaged by detecting harmonic emission at various alignments. In this study, we investigate the HHG from the water molecules, with the aim of exploring MOT for nonlinear molecules. By employing the time-dependent density functional theory, we obtain HHG spectra for different angles between the laser polarization and molecular symmetry axis. By manipulating the scanning planes (planes perpendicular to the laser propagation direction and contain the field polarization direction), specific orbitals can be selectively imaged. Particularly, a well-reconstructed highest occupied molecular orbital (HOMO) is obtained when the laser scanning plane approximately aligns with the nodal plane of HOMO-1. However, when the laser polarization deviates from the nodal plane, multiple orbitals contribute to the HHG process, and we visualize the orbital distortions resulting from such effects. Furthermore, HOMO-1, can be reconstructed when the laser scanning plane aligns with the nodal plane of HOMO. This research significantly advances the development of MOT and opens up intriguing possibilities for reconstructing orbitals of more complex molecules. • We present the extension of Molecular Orbital Tomography (MOT) from linear to nonlinear triatomic molecule H 2 O, showcasing its potential applicability to complex molecules. • Our proposed approach enables the selective imaging of distinct valence orbitals, guided by the molecular orbital structures and driving laser parameters. • We provide clear insights into the contributions of inner valence orbitals to high-order harmonic generation and their impact on MOT. [ABSTRACT FROM AUTHOR]

Published

2023

4. Tomographic Imaging of Molecular Orbitals in Length and Velocity Form.

Author

van der Zwan, Elmar V. and Lein, Manfred

Subjects

*MOLECULAR orbitals, *WAVE functions, *TOMOGRAPHY, *SCHRODINGER equation, *QUANTUM chemistry, *SYMMETRY (Physics), *HARMONIC analysis (Mathematics)

Abstract

Recently Itatani et al. [Nature 432, 876 (2004)] introduced the new concept of molecular orbital tomography, where high harmonic generation (HHG) is used to image electronic wave functions. We describe an alternative reconstruction form, using momentum instead of dipole matrix elements for the electron recombination step in HHG. We show that using this velocity-form reconstruction, one obtains better results than using the original length-form reconstruction. We provide numerical evidence for our claim that one has to resort to extremely short pulses to perform the reconstruction for an orbital with arbitrary symmetry. The numerical evidence is based on the exact solution of the time-dependent Schrödinger equation for 2D model systems to simulate the experiment. Furthermore we show that in the case of cylindrically symmetric orbitals, such as the N2 orbital that was reconstructed in the original work, one can obtain the full 3D wave function and not only a 2D projection of it. [ABSTRACT FROM AUTHOR]

Published

2007