Your search keyword '"Ning, C G"' showing total 8 results

1. Low energy (e, 2e) study from the 1t(2) orbital of CH4.

Author

Xu S, Chaluvadi H, Ren X, Pflüger T, Senftleben A, Ning CG, Yan S, Zhang P, Yang J, Ma X, Ullrich J, Madison DH, and Dorn A

Subjects

Carbon chemistry, Hydrogen chemistry, Electrons, Methane chemistry, Quantum Theory

Abstract

Single ionization of the methane (CH(4)) 1t(2) orbital by 54 eV electron impact has been studied experimentally and theoretically. The measured triple differential cross sections cover nearly a 4π solid angle for the emission of low energy electrons and a range of projectile scattering angles. Experimental data are compared with theoretical calculations from the distorted wave Born approximation and the molecular three-body distorted wave models. It is found that theory can give a proper description of the main features of experimental cross section only at smaller scattering angles. For larger scattering angles, significant discrepancies between experiment and theory are observed. The importance of the strength of nuclear scattering from the H-nuclei was theoretically tested by reducing the distance between the carbon nuclei and the hydrogen nuclei and improved agreement with experiment was found for both the scattering plane and the perpendicular plane.

Published

2012

2. Vibrational effects on the electron momentum distributions of valence orbitals of formamide.

Author

Miao YR, Deng JK, and Ning CG

Subjects

Spectrum Analysis methods, Vibration, Electrons, Formamides chemistry, Models, Chemical

Abstract

The ionization energy spectra and electron momentum distributions of formamide were investigated using the high-resolution electron momentum spectrometer in combination with high level calculations. The observed ionization energy spectra and electron momentum distributions were interpreted using symmetry adapted cluster-configuration interaction theory, outer valence Green function, and DFT-B3LYP methods. The ordering of 10a(') and 2a(") orbitals of formamide was assigned unambiguously by comparing the experimental electron momentum distributions with the corresponding theoretical results, i.e., 10a(') has a lower binding energy. In addition, it was found that the low-frequency wagging vibration of the amino group at room temperature has noticeable effects on the electron momentum distributions. The equilibrium-nuclear-positions-approximation, which was widely used in electron momentum spectroscopy, is not accurate for formamide molecule. The calculations based on the thermal average can evidently improve the agreement with the experimental momentum distributions.

Published

2012

3. Experimental and theoretical investigation of the triple differential cross section for electron impact ionization of pyrimidine molecules.

Author

Builth-Williams JD, Bellm SM, Jones DB, Chaluvadi H, Madison DH, Ning CG, Lohmann B, and Brunger MJ

Subjects

Electrons, Pyrimidines chemistry, Quantum Theory

Abstract

Cross-section data for electron impact induced ionization of bio-molecules are important for modelling the deposition of energy within a biological medium and for gaining knowledge of electron driven processes at the molecular level. Triply differential cross sections have been measured for the electron impact ionization of the outer valence 7b(2) and 10a(1) orbitals of pyrimidine, using the (e, 2e) technique. The measurements have been performed with coplanar asymmetric kinematics, at an incident electron energy of 250 eV and ejected electron energy of 20 eV, for scattered electron angles of -5°, -10°, and -15°. The ejected electron angular range encompasses both the binary and recoil peaks in the triple differential cross section. Corresponding theoretical calculations have been performed using the molecular 3-body distorted wave model and are in reasonably good agreement with the present experiment.

Published

2012

4. Dyson orbitals of N2O: electron momentum spectroscopy and symmetry adapted cluster-configuration interaction calculations.

Author

Miao YR, Ning CG, Liu K, and Deng JK

Subjects

Spectrum Analysis, Temperature, Vibration, Electrons, Nitrous Oxide chemistry, Quantum Theory

Abstract

Electron momentum spectroscopy and symmetry adapted cluster-configuration interaction (SAC-CI) theory were combined to study electron correlation effects in nitrous oxide molecule (N(2)O). The SAC-CI General-R method accurately reproduced the experimental ionization spectrum. This bench-marked method was also introduced for calculating the momentum distributions of N(2)O Dyson orbitals. Several calculated momentum distributions with different theoretical methods were compared with the high resolution experimental results. In the outer-valence region, Hartree-Fock (HF), density functional theory (DFT), and SAC-CI theory can well describe the experimental momentum distributions. SAC-CI presented a best performance among them. In the inner-valence region, HF and DFT cannot work well due to the severe breaking of the molecular orbital picture, while SAC-CI still produced an excellent description of experimental momentum profiles because it can accurately take into account electron correlations. Moreover, the thermally averaged calculation showed that the geometrical changes induced by the vibration at room temperature have no noticeable effects on momentum distribution of valence orbitals of N(2)O., (© 2011 American Institute of Physics)

Published

2011

5. Dynamical (e, 2e) studies using tetrahydrofuran as a DNA analog.

Author

Colyer CJ, Bellm SM, Lohmann B, Hanne GF, Al-Hagan O, Madison DH, and Ning CG

Subjects

Biomechanical Phenomena, Linear Energy Transfer, DNA chemistry, Electrons, Energy Transfer, Furans chemistry, Models, Biological

Abstract

Triple differential cross sections for the electron-impact ionization of the outer valence orbital of tetrahydrofuran have been measured using the (e, 2e) technique. The measurements have been performed with coplanar asymmetric kinematics, at an incident electron energy of 250 eV and at an ejected electron energy of 10 eV, over a range of momentum transfers. The experimental results are compared with theoretical calculations carried out using the molecular three-body distorted wave model. The results obtained are important for gaining an understanding of electron driven processes at a molecular level and for modeling energy deposition in living tissue.

Published

2010

6. Electron- and photon-impact ionization of furfural.

Author

Jones, D. B., Ali, E., Nixon, K. L., Limão-Vieira, P., Hubin-Franskin, M.-J., Delwiche, J., Ning, C. G., Colgan, J., Murray, A. J., Madison, D. H., and Brunger, M. J.

Subjects

ELECTRONS, PHOTONS, FURFURAL, IONIZATION (Atomic physics), VIBRATIONAL spectra, DIFFERENTIAL cross sections

Abstract

The He(I) photoelectron spectrum of furfural has been investigated, with its vibrational structure assigned for the first time. The ground and excited ionized states are assigned through ab initio calculations performed at the outer-valence Green's function level. Triple differential cross sections (TDCSs) for electron-impact ionization of the unresolved combination of the 4a"+ 21a' highest and next-highest occupied molecular orbitals have also been obtained. Experimental TDCSs are recorded in a combination of asymmetric coplanar and doubly symmetric coplanar kinematics. The experimental TDCSs are compared to theoretical calculations, obtained within a molecular 3-body distorted wave framework that employed either an orientation average or proper TDCS average. The proper average calculations suggest that they may resolve some of the discrepancies regarding the angular distributions of the TDCS, when compared to calculations employing the orbital average. [ABSTRACT FROM AUTHOR]

Published

2015

7. (e, 2e) electron momentum spectrometer with high sensitivity and high resolution.

Author

Ren, X. G., Ning, C. G., Deng, J. K., Zhang, S. F., Su, G. L., Huang, F., and Li, G. Q.

Subjects

*ELECTRONS, *SPECTROMETERS, *SPECTRUM analysis instruments, *HELIUM, *ELECTRONIC structure

Abstract

A high sensitivity and high resolution (e, 2e) electron momentum spectrometer with simultaneous detection in energy and momentum are constructed. The design and performance of the spectrometer are reported. The orbital electron density distributions are obtained accurately and rapidly by using this spectrometer equipped with a double toroidal analyzer. The experimental results on argon and helium exhibit the significant improvements in coincidence count rates, resolution, sensitivity and obtainment of a wide range of adjustable experimental impact energies, which are crucial for further electron momentum spectroscopy studying electronic structure and electron correlation in complex systems. [ABSTRACT FROM AUTHOR]

Published

2005

8. Calculation of Dyson orbitals using a symmetry-adapted-cluster configuration-interaction method for electron momentum spectroscopy: N2 and H2O.

Author

Miao, Y. R., Ning, C. G., and Deng, J. K.

Subjects

*SYMMETRY (Physics), *ATOMIC orbitals, *MATHEMATICAL symmetry, *DISTRIBUTION (Probability theory), *SPECTRUM analysis, *ELECTRONS, *IONIZATION (Atomic physics)

Abstract

The symmetry-adapted-cluster (SAC) configuration-interaction (CI) theory was introduced to interpret the non-coplanar symmetric (e,2e) results. Dyson orbitals derived from the bench-marked SAC CI general-R method were utilized for computing the electron momentum distributions. The corresponding excitation energies and spectroscopic factors can be used to reproduce the ionization spectra. The implementation was demonstrated by examples of N2 and H2O. The electron momentum distributions calculated using SAC CI method were compared with recent experimental results, as well as the Hartree-Fock and density-functional-theory calculations. The SAC CI method gave the best performance on the description of the experimental momentum distributions. It was found that the electron momentum distributions of Dyson orbitals related to the satellite lines can be notably different from those of their parent orbitals due to the electron correlation in the initial target states. Present work demonstrated that the SAC CI theory is a very useful and accurate tool for interpreting high-resolution electron momentum spectroscopy results. [ABSTRACT FROM AUTHOR]

Published

2011