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2. Monitoring non-adiabatic dynamics in CS2 with time- and energy-resolved photoelectron spectra of wavepackets

Author

Kwanghsi Wang, Vincent McKoy, Albert Stolow, Michael S. Schuurman, and Paul Hockett

Subjects
010304 chemical physics, Chemistry, Wave packet, Polyatomic ion, Ab initio, General Physics and Astronomy, Photoionization, Conical intersection, 01 natural sciences, Spectral line, Ab initio multiple spawning, 0103 physical sciences, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, 010306 general physics, Adiabatic process
Abstract

We report results from a novel fully ab initio method for simulating the time-resolved photoelectron angular distributions around conical intersections in CS_2. The technique employs wavepacket densities obtained with the multiple spawning method in conjunction with geometry- and energy-dependent photoionization matrix elements. The robust agreement of the calculated molecular-frame photoelectron angular distributions with measured values for CS_2 demonstrates that this approach can successfully illuminate, and disentangle, the underlying coupled nuclear and electronic dynamics around conical intersections in polyatomic molecules.

Published
2017

6. Local orbitals in electron scattering calculations*

Author

Carl Winstead and Vincent McKoy

Subjects
Physics, 010304 chemical physics, Scattering, Molecular orbital theory, Cubic harmonic, 01 natural sciences, Atomic and Molecular Physics, and Optics, Delocalized electron, Linear combination of atomic orbitals, Quantum mechanics, 0103 physical sciences, Molecular orbital, 010306 general physics, Scaling, Basis set
Abstract

We examine the use of local orbitals to improve the scaling of calculations that incorporate target polarization in a description of low-energy electron-molecule scattering. After discussing the improved scaling that results, we consider the results of a test calculation that treats scattering from a two-molecule system using both local and delocalized orbitals. Initial results are promising.

Published
2016

7. Interaction of slow electrons with methyl phosphate esters

Author

Vincent McKoy and Carl Winstead

Subjects
Shape resonance, Electron, Condensed Matter Physics, Phosphate, Trimethyl phosphate, Elastic collision, chemistry.chemical_compound, chemistry, Physical chemistry, Molecule, Organic chemistry, Physical and Theoretical Chemistry, Instrumentation, Phosphoric acid, Electron scattering, Caltech Library Services, Spectroscopy
Abstract

We report computed cross sections for low-energy elastic collisions of electrons with the methyl esters of phosphoric acid, monomethyl, dimethyl, and trimethyl phosphate, and with phosphoric acid itself. For phosporic acid and monomethyl phosphate, polarization effects are included in the calculation, while the two larger molecules are treated in the static-exchange approximation, that is, with polarization neglected. The integral elastic cross sections exhibit broad shape resonances above 5 eV that give rise to strong variations in the differential cross section with energy. However, no shape resonances are evident below 5 eV. We compare our results to previous calculations and measurements and discuss their relevance to electron-induced damage to the DNA backbone.

Published
2008

8. Electron impact dissociation of oxygen-containing molecules–A critical review

Author

Charles P. Malone, J. W. McConkey, Paul V. Johnson, Isik Kanik, C. Winstead, and Vincent McKoy

Subjects
Physics, General Physics and Astronomy, chemistry.chemical_element, Electron, Oxygen, Diatomic molecule, Dissociation (chemistry), chemistry, Chemical physics, Ionization, Molecule, Atomic physics, Excitation, Electron ionization
Abstract

The dissociation of a wide range of oxygen-containing molecules following impact with electrons of carefully controlled energy is critically reviewed. Molecules considered range from diatomics, like O_2 and CO, to large molecules of biological and technological interest. Dissociation mechanisms are discussed and, where possible, quantitative data for the various possible processes, ionization, attachment, dissociation, excitation, emission etc., are presented. Gaps and discrepancies in our current data base are highlighted. Both graphical and tabular data are presented.

Published
2008

9. Dynamics of the Dissociating Uracil Anion Following Resonant Electron Attachment

Author

Carl Winstead, Yu Kawarai, Daniel Slaughter, Yoshiro Azuma, Thorsten Weber, Ali Belkacem, and Vincent McKoy

Subjects
Microscope, Chemistry, Electronic structure, Electron, electron attachment, Kinetic energy, Molecular physics, Dissociation (chemistry), Nucleobase, law.invention, Ion, resonant dissociation, transient anion, anion dynamics, DEA, law, General Materials Science, Physical and Theoretical Chemistry, Atomic physics, Electron scattering, electron impact excitation
Abstract

We report a combined experimental and theoretical investigation of dissociative electron attachment (DEA) to the nucleobase uracil. Using ion momentum imaging experiments employing a DEA reaction microscope we have measured 3-dimensional momentum distributions of specific anionic fragments following DEA to uracil by 6 eV electrons. From the measured anion fragment kinetic energy we determine the possible dissociation pathways and the total kinetic energy release. We employ electronic structure and electron scattering calculations to determine the probability for electron attachment in the molecular frame. Combining these calculations with the imaging measurements, we reveal several key features of the coupled electronic and nuclear dynamics of DEA.

Published
2015

10. Dipole and nondipole photoionization of molecular hydrogen

Author

Vincent McKoy, Elliot P. Kanter, Stephen H. Southworth, Bertold Krässig, B. Zimmermann, and Ralf Wehlitz

Subjects
Physics, media_common.quotation_subject, Hydrogen molecule, Photoionization, Discrete dipole approximation, Photoelectric effect, Photon energy, Asymmetry, Atomic and Molecular Physics, and Optics, Dipole, Physics::Atomic Physics, Atomic physics, Anisotropy, media_common
Abstract

We describe a theoretical approach to molecular photoionization that includes first-order corrections to the dipole approximation. The theoretical formalism is presented and applied to photoionization of H_2 over the 20- to 180-eV photon energy range. The angle-integrated cross section σ, the electric dipole anisotropy parameter β_e, the molecular alignment anisotropy parameter β_m, and the first-order nondipole asymmetry parameters γ and δ were calculated within the single-channel, static-exchange approximation. The calculated parameters are compared with previous measurements of σ and β_m and the present measurements of β_e and γ+3δ. The dipole and nondipole angular distribution parameters were determined simultaneously using an efficient, multiangle measurement technique. Good overall agreement is observed between the magnitudes and spectral variations of the calculated and measured parameters. The nondipole asymmetries of He 1s and Ne 2p photoelectrons were also measured in the course of this work.

Published
2015

11. Probing the transition from non-localization to localization by K-shell photoemission from isotope-substituted N2

Author

Axel Reinköster, Jens Viefhaus, Uwe Becker, Vincent McKoy, Burkhard Langer, Toralf Lischke, Sanja Korica, Georg Prümper, Rainer Hentges, Oliver Geßner, Markus Braune, Slobodan Cvejanovic, Björn Zimmermann, and Daniel Rolles

Subjects
Radiation, Isotope, Chemistry, Kinetic isotope effect, Point reflection, Physics::Atomic and Molecular Clusters, Electron shell, Physics::Atomic Physics, Electronic structure, Electron, Atomic physics, Diatomic molecule, Homonuclear molecule
Abstract

In homonuclear diatomic molecules such as N_2, the inversion symmetry of the system causes non-local, coherent behavior of the otherwise localized core holes. The non-locality of the electron emission and the remaining core hole changes in a continuous way into partially localized behaviour if a gradual breakdown of the inversion symmetry is induced by isotope substitution. This is reflected by a loss of interference and a parity mixing of the outgoing photoelectron waves. Our results represent the first experimentally observed isotope effect on the electronic structure of a diatomic molecule.

Published
2006

12. Isotope-induced partial localization of core electrons in the homonuclear molecule N2

Author

Jens Viefhaus, Vincent McKoy, Oliver Geßner, Daniel Rolles, Rainer Hentges, Georg Prümper, Axel Reinköster, Björn Zimmermann, Sanja Korica, Uwe Becker, Markus Braune, Toralf Lischke, Slobodan Cvejanovic, and Burkhard Langer

Subjects
Multidisciplinary, Core electron, Chemistry, Degenerate energy levels, Coherent states, Electron, Electronic structure, Atomic physics, Diatomic molecule, Homonuclear molecule, Coherence (physics)
Abstract

Because of inversion symmetry and particle exchange, all constituents of homonuclear diatomic molecules are in a quantum mechanically non-local coherent state; this includes the nuclei and deep-lying core electrons. Hence, the molecular photoemission can be regarded as a natural double-slit experiment: coherent electron emission originates from two identical sites, and should give rise to characteristic interference patterns. However, the quantum coherence is obscured if the two possible symmetry states of the electronic wavefunction ('gerade' and 'ungerade') are degenerate; the sum of the two exactly resembles the distinguishable, incoherent emission from two localized core sites. Here we observe the coherence of core electrons in N(2) through a direct measurement of the interference exhibited in their emission. We also explore the gradual transition to a symmetry-broken system of localized electrons by comparing different isotope-substituted species--a phenomenon analogous to the acquisition of partial 'which-way' information in macroscopic double-slit experiments.

Published
2005

13. Carbon K-shell photoelectron angular distribution from fixed-in-space CO2molecules

Author

Vincent McKoy, Inosuke Koyano, L. Schmidt, K. Kubozuka, R. Dörner, Isao H. Suzuki, Hiroaki Yoshida, Kiyoshi Ueda, Achim Czasch, Masahiko Takahashi, Amine Cassimi, Norio Saito, A. De Fanis, B. Zimmermann, Kwanghsi Wang, and M. Machida

Subjects
Physics, Shape resonance, Triatomic molecule, Electron shell, chemistry.chemical_element, Photoionization, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Spectral line, chemistry, Ionization, Physics::Atomic and Molecular Clusters, Perpendicular, Physics::Atomic Physics, Atomic physics, Carbon
Abstract

Measurements of photoelectron angular distributions for carbon K-shell ionization of fixed-in-space CO2 molecules with the molecular axis oriented along, perpendicular and at 45 degrees to the electric vector of the light are reported. The major features of these measured spectra are fairly well reproduced by calculations employing a relaxed-core Hartree-Fock approach. In contrast to the angular distribution for K-shell ionization of N-2, which exhibits a rich structure dominated by the f-wave (l = 3) at the shape resonance, the angular distribution for carbon K-shell photoionization of CO2 is quite unstructured over the entire observed range across the shape resonance.

Published
2002

14. Rotationally resolved photoionization dynamics of hot CO fragmented from OCS

Author

Ellen H. G. Backus, Cornelis A. de Lange, Kwanghsi Wang, Vincent McKoy, Maurice H. M. Janssen, Anouk M. Rijs, Nicholas P. C. Westwood, HIMS Other Research (FNWI), Physical Chemistry, and Atoms, Molecules, Lasers

Subjects
Chemistry, Photodissociation, General Physics and Astronomy, Photoionization, Ion, symbols.namesake, X-ray photoelectron spectroscopy, Ionization, Angular momentum coupling, Rydberg formula, symbols, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Physical and Theoretical Chemistry, Rydberg state, Atomic physics, Physics::Chemical Physics, SDG 6 - Clean Water and Sanitation
Abstract

The photoionizationdynamics of rotationally hot CO, photodissociated from OCS, have been studied using laser photoelectron spectroscopy via the intermediate B^1Σ^+Rydberg state leading to the X^2Σ^+ of the ion. The photodissociation of OCS near 230 nm produces rotationally hot, but vibrationally cold CO (X^1Σ^+,N″,v″=0,1) fragments along with S (^1D) atoms. These high rotational levels show photoelectron spectra with a very strong ΔN=0 transition and weaker ΔN=±1, ±2, and ±3 transitions. Agreement between measured and calculated spectra is good and suggests that there is significant angular momentum coupling in the photoelectron orbital. In the ionization step not only Δv=0, but also off-diagonal, non-Franck–Condon (Δv≠0) transitions are observed. The intensities of these transitions vary strongly within the region studied and can be explained by the excitation of superexcited Rydberg states with an A^2Π core.

Published
2002

15. Low-energy elastic electron scattering from isobutanol and related alkyl amines

Author

C. Navarro, Márcio H. F. Bettega, Carl Winstead, Murtadha A. Khakoo, F. M. Silva, Kamil Fedus, Vincent McKoy, and Leigh Hargreaves

Subjects
Physics, Elastic scattering, Isobutanol, Scattering, Analytical chemistry, Electron, Atomic and Molecular Physics, and Optics, 3. Good health, chemistry.chemical_compound, Isobutylamine, chemistry, Molecule, Isopropylamine, Ethylamine, Atomic physics
Abstract

Normalized experimental differential and integral cross sections for vibrationally elastic scattering of low-energy electrons from isobutanol (C_4H_9OH)are presented. The differential cross sections are measured at incident energies from 1 to 100 eV and scattering angles from 5° to 130°. These cross sections are compared to earlier experimental and theoretical results for isobutanol and n-butanol, as well as to results for smaller alcohols and for alkanes. Further comparisons are made with calculated cross sections for isobutylamine (C_4H_9NH_2)and for smaller amines, including ethylamine (C_2H_5NH_2), dimethylamine (CH_3NHCH_3)the two C_3H_7NH_2 isomers n-propylamine and isopropylamine, and ethylene diamine (NH_2C_2H_4NH_2). The calculated cross sections are obtained using the Schwinger multichannel method. The comparisons illuminate the role of molecular structure in determining the angular distribution of resonantly scattered electrons.

Published
2014

16. Time-Resolved Photoelectron Spectra ofCS2: Dynamics at Conical Intersections

Author

Michael S. Schuurman, Kwanghsi Wang, Paul Hockett, and Vincent McKoy

Subjects
Physics, Matrix (mathematics), Wave packet, Polyatomic ion, Physics::Atomic and Molecular Clusters, Ab initio, General Physics and Astronomy, Molecule, Physics::Atomic Physics, Conical surface, Photoionization, Molecular physics, Spectral line
Abstract

We report results of the application of a fully ab initio approach for simulating time-resolved molecular-frame photoelectron angular distributions around conical intersections in ${\mathrm{CS}}_{2}$. The technique employs wave packet densities obtained with the multiple spawning method in conjunction with geometry- and energy-dependent photoionization matrix elements. The robust agreement of these results with measured molecular-frame photoelectron angular distributions for ${\mathrm{CS}}_{2}$ demonstrates that this technique can successfully elucidate, and disentangle, the underlying nuclear and photoionization dynamics around conical intersections in polyatomic molecules.

Published
2014

17. Rotationally resolved photoionization: Influence of the 4σ→kσ shape resonance on CO+(B 2Σ+) rotational distributions

Author

Vincent McKoy, George R. Farquar, Erwin D. Poliakoff, Kwanghsi Wang, and J. Scott Miller

Subjects
Shape resonance, Chemistry, Ionization, General Physics and Astronomy, Substructure, Ionic bonding, Photoionization, Physical and Theoretical Chemistry, Atomic physics, Kinetic energy, Spectral line, Ion
Abstract

We present experimental and theoretical results on rotational distributions of CO^+ (B^2Σ^+) photoions. Rotational distributions were determined for both the v^+=0 and v^+=1 vibrational levels following photoionization of cold (T_0≈9K) neutral CO target molecules. Data were generated using dispersed ionic fluorescence over a wide range of photoelectron kinetic energies, 0⩽E_k⩽120eV, which allows one to interrogate the ionization dynamics. This wide spectral coverage permits illustrative comparisons with theory, and calculated spectra are presented to interpret the data. In particular, the comparison between theory and experiment serves to identify the strong continuum resonant enhancement at hν_(exc)≈35eV in the l=3 partial wave of the 4σ→kσ ionization channel, as this feature has profound effects on the ion rotational distributions over a wide range of energy. Second, there are differences between the rotational substructure for the v^+=0 and v^+=1 vibrational levels. All of the experimentally observed features and trends are reproduced by theory, and the consequences of these comparisons are discussed.

Published
2001

18. Energy- and angle-resolved pump–probe femtosecond photoelectron spectroscopy: Molecular rotation

Author

Vincent McKoy, Yasuki Arasaki, Kazuo Takatsuka, and Kwanghsi Wang

Subjects
Coupling, X-ray photoelectron spectroscopy, Photoemission spectroscopy, Chemistry, Wave packet, Femtosecond, Physics::Atomic and Molecular Clusters, Rotation around a fixed axis, General Physics and Astronomy, Physical and Theoretical Chemistry, Atomic physics, Spectral line, Ultraviolet photoelectron spectroscopy
Abstract

We have incorporated a classical treatment of molecular rotation into our formulation of energy- and angle-resolved pump–probe photoelectron spectroscopy. This classical treatment provides a useful approach to extracting the photoelectron signal primarily associated with vibrational dynamics in cases where rotational motion is slow and the coupling between rotational and vibrational motion is weak. We illustrate its applicability with pump–probe photoelectron spectra for wave packets on the ^1Σ^+_u double-minimum state of Na_2.

Published
2001

19. Rotationally resolved photoelectron spectroscopy of hot N2 formed in the photofragmentation of N2O

Author

Ellen H. G. Backus, Anouk M. Rijs, Kwanghsi Wang, Cornelis A. de Lange, Maurice H. M. Janssen, Vincent McKoy, Physical Chemistry, Atoms, Molecules, Lasers, and HIMS Other Research (FNWI)

Subjects
Resonance-enhanced multiphoton ionization, Chemistry, Physics::Instrumentation and Detectors, Photodissociation, General Physics and Astronomy, Spectral line, X-ray photoelectron spectroscopy, Excited state, Ionization, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Astrophysics::Earth and Planetary Astrophysics, Physical and Theoretical Chemistry, Atomic physics, Rydberg state, SDG 6 - Clean Water and Sanitation, Excitation
Abstract

The photoionizationdynamics of rotationally hot molecular nitrogen are studied employing resonance enhanced multiphoton ionization in combination with photoelectron spectroscopy.Photodissociation of N_2O at ∼203 nm results in highly rotationally excited N2 fragments in X ^1∑^+_g (N″,v″=0,1) states and O atoms in the excited ^1D_2 state. Photoelectron detection of the rotationally hot N_2 states is performed by a two-photon excitation to the lowest a″ ^1∑^+_g Rydberg state followed by one-photon ionization. The large number of observed rotational levels, from N′=49 up to N′=94, results in improved rotational parameters for a″ ^1∑^+_g (v′=0). In addition, experimental and theoretical rotationally resolved photoelectron spectra of the a″ ^1∑^+_g (v′=0,1;N′) state are presented. In these spectra only ΔN = N^+ − N′ = even transitions are observed, with a dominant ΔN=0 peak and rather weak ΔN = ±2 peaks. The one-photon ionization is dominated by ejection of electrons in p and f partial waves. The agreement between experimental and calculated spectra is excellent.

Published
2001

20. Probing wavepacket dynamics with femtosecond energy- and angle-resolved photoelectron spectroscopy

Author

Kwanghsi Wang, Yasuki Arasaki, Vincent McKoy, and Kazuo Takatsuka

Subjects
Radiation, Chemistry, Photoemission spectroscopy, Wave packet, Physics::Optics, Electronic structure, Photoionization, Condensed Matter Physics, Laser, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, law.invention, X-ray photoelectron spectroscopy, law, Femtosecond, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, Spectroscopy, Ultraviolet photoelectron spectroscopy
Abstract

Femtosecond energy- and angle-resolved pump-probe photoelectron spectra of wavepackets in a double-minimum state of Na 2 are studied. These studies illustrate that a robust description of the photoionization dynamics significantly enhances the utility of time-resolved photoelectron spectroscopy as a probe of wavepackets and of the evolution of electronic structure, particularly in regions of avoided crossings, and that the dependence of these angular distributions on the relative polarizations of the pump and probe lasers can be exploited to monitor molecular alignment.

Published
2000

21. Parallel computational studies of electron–molecule collisions

Author

Vincent McKoy and Carl Winstead

Subjects
Computer program, Field (physics), Hardware and Architecture, Scattering, Computer science, Polyatomic ion, Message passing, General Physics and Astronomy, Collision problem, Electronic structure, Electron, Computational physics
Abstract

Molecular electronic structure calculations involving unbound or scattering states occupy a small but important territory adjacent to the broader field of computational chemistry. Besides providing fundamental scientific insights, such calculations can provide essential data for technological applications, provided that reliable calculations can be carried out for the relatively large molecules of interest. In this article, we describe one approach to the electron–molecule collision problem and discuss how that approach has been adapted to parallel computers – from monolithic supercomputers to workstation clusters – in order to achieve the levels of performance necessary to address collisions with larger polyatomic targets.

Published
2000

22. Femtosecond energy- and angle-resolved photoelectron spectroscopy

Author

Kwanghsi Wang, Kazuo Takatsuka, Vincent McKoy, and Yasuki Arasaki

Subjects
Chemistry, Wave packet, General Physics and Astronomy, Photoelectron photoion coincidence spectroscopy, Photoionization, Spectral line, X-ray photoelectron spectroscopy, Ionization, Femtosecond, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, Ultraviolet photoelectron spectroscopy
Abstract

We present a formulation of energy- and angle-resolved photoelectron spectra for femtosecond pump–probe ionization of wave packets and results of its application to the ^1Σ^+_u double-minimum state of aligned Na_2. The formulation is well-suited for inclusion of the underlying dynamics of molecular photoionization and its dependence on molecular geometry. Results are presented for three typical pump laser energies selected so as to investigate qualitatively different patterns of the spatio-temporal propagation of wave packets on the double-minimum potential curve and of their associated photoelectron spectra. Photoelectron angular distributions are also reported for different orientations of linearly polarized pump and probe pulses. The resulting photoelectron spectra illustrate the importance of a proper description of the underlying photoionization amplitudes and their dependence on geometry for unraveling wave packet dynamics from pump–probe photoelectron signals in nonadiabatic regions where the electronic structure evolves rapidly with geometry. The dependence of these photoelectron angular distributions on relative orientation of the molecule and polarization of the probe pulse are also seen to be potentially useful for real-time monitoring of molecular rotation.

Published
2000

23. Introductory Lecture: Probing wavepacket dynamics with femtosecond energy- and angle-resolved photoelectron spectroscopy

Author

Vincent McKoy, Kwanghsi Wang, Yasuki Arasaki, and Kazuo Takatsuka

Subjects
Physics::Instrumentation and Detectors, Chemistry, Wave packet, Ionic bonding, Photoionization, Electronic structure, Diatomic molecule, Spectral line, X-ray photoelectron spectroscopy, Femtosecond, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, Caltech Library Services
Abstract

Several recent studies have demonstrated how well-suited femtosecond time-resolved photoelectron spectra are for mapping wavepacket dynamics in molecular systems. Theoretical studies of femtosecond photoelectron spectra which incorporate a robust description of the underlying photoionization dynamics should enhance the utility of such spectra as a probe of wavepackets and of the evolution of electronic structure. This should be particularly true in regions of avoided crossings where the photoionization amplitudes and electronic structure may evolve rapidly with geometry. In this paper we present the results of studies of energy- and angle-resolved femtosecond photoelectron spectra for wavepackets in the diatomic systems, Na2 and NaI. Both cases involve motion through regions of avoided crossings. In Na2, however, wavepacket motion occurs on a single adiabatic potential with an inner and outer well and a barrier between them, while in NaI wavepackets move on the nonadiabatically coupled covalent (NaI) and ionic (Na+I−) potentials. Results of these studies will be used to illustrate the insight into wavepacket dynamics that time-resolved photoelectron spectra provide. For example, in the case of NaI these angle-resolved photoelectron spectra seem to offer some promise for probing real-time dynamics of intramolecular electron transfer occurring in the crossing region of the ionic and covalent states.

Published
2000

24. Collisions of low-energy electrons with CO2

Author

Vincent McKoy, Carl Winstead, and Chuo-Han Lee

Subjects
Scattering cross-section, Physics, Low energy, Excited state, General Physics and Astronomy, Zero-point energy, Electron, Physical and Theoretical Chemistry, Atomic physics, Polarization (electrochemistry), Excitation
Abstract

We report cross sections for collisions of low-energy electrons with carbon dioxide obtained by the Schwinger multichannel variational method.Elastic cross sections are obtained in the static-exchange-plus-polarization approximation. We pay particular attention to the position of the ^2Π_u resonance and to the strong enhancement in the integral cross section near zero energy, both prominent features whose accurate treatment requires an accounting for polarization effects. To include such effects in the resonant symmetry, we use an objective and physically motivated criterion to construct a set of configurations that accurately accounts for polarization while avoiding overcorrelation. In addition, we study the origin of the nonisotropic behavior of the elastic differential cross section at very low energies and conclude that it is caused by significant contributions from vibrationally excited CO_2. Cross sections from threshold to 50 eV for excitation of the ^3Σ^+_u, ^1Δ_u, ^3Δ_u, ^3Σ^−_u, and ^1Σ^−_u states that arise from the (^1π_g → ^2π_u) transition are presented for the first time.

Published
1999

25. Femtosecond energy- and angle-resolved photoelectron spectra

Author

Kazuo Takatsuka, Yasuki Arasaki, Kwanghsi Wang, and Vincent McKoy

Subjects
Chemistry, Linear polarization, Wave packet, General Physics and Astronomy, Electronic structure, Photoionization, Polarization (waves), Ionization, Femtosecond, Physics::Atomic and Molecular Clusters, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, Ultraviolet photoelectron spectroscopy
Abstract

We present a formulation of energy- and angle-resolved photoelectron spectra for femtosecond pump–probe ionization of wave packets and results of its application to the ^1Σ^+_u double-minimum state of aligned Na_2. The formulation is well-suited for inclusion of the underlying dynamics of molecular photoionization and its dependence on molecular geometry. Results are presented for three typical pump laser energies selected so as to investigate qualitatively different patterns of the spatio-temporal propagation of wave packets on the double-minimum potential curve and of their associated photoelectron spectra. Photoelectron angular distributions are also reported for different orientations of linearly polarized pump and probe pulses. The resulting photoelectron spectra illustrate the importance of a proper description of the underlying photoionization amplitudes and their dependence on geometry for unraveling wave packet dynamics from pump–probe photoelectron signals in nonadiabatic regions where the electronic structure evolves rapidly with geometry. The dependence of these photoelectron angular distributions on relative orientation of the molecule and polarization of the probe pulse are also seen to be potentially useful for real-time monitoring of molecular rotation.

Published
1999

26. Swarm Studies and Inelastic Electron-Molecule Collisions : Proceedings of the Meeting of the Fourth International Swarm Seminar and the Inelastic Electron-Molecule Collisions Symposium, July 19–23, 1985, Tahoe City, California, USA

Author

Leanne C. Pitchford, B. Vincent McKoy, Ara Chutjian, Sandar Trajmar, Leanne C. Pitchford, B. Vincent McKoy, Ara Chutjian, and Sandar Trajmar

Subjects
Electron-molecule collisions--Congresses, Electron swarms--Congresses
Abstract

This volume presents the contributions of participants in the Symposium on Swarm Studies and Inelastic Electron-Molecule Collisions, held on July 19-23, 1985, in Tahoe City, California. This was a joint meeting of the Fourth International Swarm Seminar and the Electron-Molecule Collisions Symposium which have been traditionally separate satellite symposia to the International Conference on the Physics of Electronic and Atomic Collisions (ICPEAC). In the early stages of planning for these two satellite symposia to the XIVth ICPEAC, a group of us recognized the significant scientific merit and advantages of having a joint symposium. This idea was particularly appealing due to a large mutual interest in important advances (theoretical, experimental, and modeling) in both fields, and because it provides a forum to bring together a single-collision point of view with a multiple-collision one. For example, studies of multiple-term solutions to Boltzmann's equation and their application to swarm systems are intrinsically coupled to the availability of both integral and differential cross-sections for electron-molecule collisions. In tum, experimental and theoretical studies of these electron-molecule scattering cross-sections are becoming quite sophisticated, accurate, and comprehensive. Furthermore, in swarm studies, computational and experimental methods have advanced to the point where detailed and meaningful comparison with, and use of, single-collision beam data is now possible. More­ over, recent experimental advances in the study of single-collision electron at­ tachment phenomena have provided a significant overlap with swarm data and extension to subthermal energies.

Published
2012

27. Parallel computing and the generation of basic plasma data

Author

Vincent McKoy, Carl Winstead, and Chuo-Han Lee

Subjects
Physics, Parallel processing (DSP implementation), Semiconductor device fabrication, Polyatomic ion, Principal mechanism, Measure (physics), Surfaces and Interfaces, Plasma, Electron, Atomic physics, Condensed Matter Physics, Surfaces, Coatings and Films, Computational physics
Abstract

Comprehensive simulations of the processing plasmas used in semiconductor fabrication will depend on the availability of basic data for many microscopic processes that occur in the plasma and at the surface. Cross sections for electron collisions, a principal mechanism for producing reactive species in these plasmas, are among the most important such data; however, electron-collision cross sections are difficult to measure, and the available data are, at best, sketchy for the polyatomic feed gases of interest. While computational approaches to obtaining such data are thus potentially of significant value, studies of electron collisions with polyatomic gases at relevant energies are numerically intensive. In this article, we report on the progress we have made in exploiting large-scale distributed-memory parallel computers, consisting of hundreds of interconnected microprocessors, to generate electron-collision cross sections for gases of interest in plasma simulations.

Published
1998

28. Rotationally resolved multiphoton ionization photoelectron spectroscopy of the [a 1Δ]3dπ 2Φ and [a 1Δ]5pπ 2Φ Rydberg states of the SH radical

Author

Wybren Jan Buma, Vincent McKoy, C.A. de Lange, J. B. Milan, Kwanghsi Wang, and HIMS former research (FNWI)

Subjects
symbols.namesake, Angular momentum, X-ray photoelectron spectroscopy, Ab initio quantum chemistry methods, Chemistry, Ionization, Rydberg formula, symbols, General Physics and Astronomy, Ionic bonding, Physical and Theoretical Chemistry, Atomic physics, Spectral line
Abstract

Experimental and theoretical results on the rotationally resolved photoelectron spectra of the [a ^1Δ]3dπ^2Φ(v'=0) and the [a^ 1Δ]5pπ^2Φ(v'=0) Rydberg states of the SH radical are presented. In particular, for the former state, ionization via a large number of members of different rotational branches is considered. The interplay between experiment and ab initio calculations, including alignment, allows for a detailed interpretation of the results. Asymmetries apparent in the rotational ionic distributions and the observed suppression of transitions involving a large change in angular momentum can be explained on the basis of the theory.

Published
1997

29. Time-resolved photoelectron spectra of CS2: dynamics at conical intersections

Author

Kwanghsi, Wang, Vincent, McKoy, Paul, Hockett, and Michael S, Schuurman

Abstract

We report results of the application of a fully ab initio approach for simulating time-resolved molecular-frame photoelectron angular distributions around conical intersections in CS2. The technique employs wave packet densities obtained with the multiple spawning method in conjunction with geometry- and energy-dependent photoionization matrix elements. The robust agreement of these results with measured molecular-frame photoelectron angular distributions for CS2 demonstrates that this technique can successfully elucidate, and disentangle, the underlying nuclear and photoionization dynamics around conical intersections in polyatomic molecules.

Published
2013

31. Low-energy elastic electron scattering by acetylene

Author

C. Navarro, Carl Winstead, Murtadha A. Khakoo, Leigh Hargreaves, A. Gauf, G. Balch, and Vincent McKoy

Subjects
Formamide, Physics, chemistry.chemical_compound, Low energy, chemistry, Acetylene, Scattering, Formic acid, Acetaldehyde, Elastic electron, Electron, Molecular physics, Atomic and Molecular Physics, and Optics
Abstract

We report results from a combined experimental and computational study of low-energy electron interactions with acetaldehyde in the gas phase. Differential cross sections for elastic electron scattering were measured at selected incident energies from 1 to 50 eV, while corresponding first-principles calculations were carried out up to 30 eV. Integral and momentum-transfer cross sections were derived from the angle-differential data. The role of resonances in the scattering is examined and comparison is made to previous results for acetaldehyde and for its analogs, formamide and formic acid.

Published
2013

32. Rotationally resolved photoelectron spectroscopy of the vanadium dimer

Author

Vincent McKoy and Kwanghsi Wang

Subjects
X-ray photoelectron spectroscopy, Chemistry, Ionization, General Physics and Astronomy, Vanadium, chemistry.chemical_element, Photoionization, Physical and Theoretical Chemistry, Atomic physics, Ground state, Excitation, Spectral line, Ion
Abstract

Results of calculations of the rotationally resolved photoelectron spectra of the V_2^+ ground state obtained by two-color excitation via the A ^3Π_u ← X^3 Σ_g^- system are reported and compared with recent pulsed-field-ionization zero-kinetic-energy measurements of these spectra. Agreement between the measured and calculated spectra is very encouraging. Both illustrate that the spin-orbit interaction plays an important role in photoionization of the A ^3Π_u state of V_2 leading to the X^4Σ_g^− state of V_2^+. Striking differences are seen in the ion rotational distributions for ionization via the A ^3Π_(1u) and A ^3Π_(2u spin-orbit components.

Published
1996

33. Absolute differential cross sections for electron-impact excitation of CO near threshold: II. The Rydberg states of CO

Author

Vincent McKoy, U. Mayer, K. Jung, Carl Winstead, H. P. Pritchard, H. Ehrhardt, and J. Zobel

Subjects
Physics, Near threshold, symbols.namesake, Scattering, Rydberg formula, symbols, Atomic physics, Condensed Matter Physics, Caltech Library Services, Atomic and Molecular Physics, and Optics, Excitation, Differential (mathematics), Electron ionization
Abstract

Absolute differential cross sections for electron-impact excitation of Rydberg states of CO have been measured from threshold to 3.7 eV above threshold and for scattering angles between 20° and 140°. Measured excitation functions for the b 3Σ+, B 1Σ+ and E 1π states are compared with cross sections calculated by the Schwinger multichannel method. The behaviour of the excitation functions for these states and for the j 3Σ+ and C 1Σ+ states is analysed in terms of negative-ion states. One of these resonances has not been previously reported.

Published
1996

34. Vibrational branching ratios in photoionization of CO and N2

Author

Vincent McKoy, Kwanghsi Wang, R. M. Rao, G. J. Rathbone, and Erwin D. Poliakoff

Subjects
chemistry.chemical_classification, Shape resonance, Low energy, Scattering, Chemistry, General Physics and Astronomy, Molecule, Compounds of carbon, Photoionization, Physical and Theoretical Chemistry, Atomic physics, Branching (polymer chemistry), Caltech Library Services
Abstract

We report results of experimental and theoretical studies of the vibrational branching ratios for CO 4sigma(-1) photoionization from 20 to 185 eV. Comparison with results for the 2sigma(u)(-1) channel of the isoelectronic N-2 molecule shows the branching ratios for these two systems to be qualitatively different due to the underlying scattering dynamics: CO has a shape resonance at low energy but lacks a Cooper minimum at higher energies whereas the situation is reversed for N-2.

Published
2004

35. Absolute cross sections for electron collisions with diacetylene: elastic scattering, vibrational excitation and dissociative attachment

Author

Juraj Fedor, Vincent McKoy, Michael Allan, Carl Winstead, Lidija Andric, Bogdan C. Ibǎnescu, and Olivier May

Subjects
Elastic scattering, History, Diacetylene, Electron, Computer Science Applications, Education, chemistry.chemical_compound, chemistry, Electron attachment, Physics::Atomic and Molecular Clusters, Atomic physics, Physics::Chemical Physics, Electron ionization, Excitation
Abstract

We present absolute experimental cross sections for elastic scattering, vibrational excitation by electron impact and for dissociative electron attachment to 1,3-butadiyne, as well as calculations of the elastic cross sections.

Published
2012

36. High-Resolution Photoelectron Spectroscopy of Molecules

Author

Vincent McKoy and Kwanghsi Wang

Subjects
Autoionization, X-ray photoelectron spectroscopy, Chemistry, Physics::Atomic and Molecular Clusters, High resolution, Molecule, Physics::Atomic Physics, Photoionization, Physical and Theoretical Chemistry, Atomic physics, Molecular physics, Spectral line
Abstract

Rotationally resolved photoelectron spectra can provide significant insight into the underlying dynamics of molecular photoionization. Here, we discuss and compare results of recent theoretical studies of rotationally resolved photoelectron spectra with measurements for molecules such as HBr, OH, NO, N2, CO, H20, H2CO, and CH3. These studies reveal the rich dynamics of quantum-state-specific studies of molecular photoionization and provide a robust description of key spectral features resulting from Cooper minima, autoionization, alignment, partial-wave mixing, and interference in related experimental studies.

Published
1995

37. Photoion rotational distributions from near‐threshold to deep in the continuum

Author

Kwanghsi Wang, Sandeep Kakar, R. M. Rao, Erwin D. Poliakoff, A. G. Mihill, Vincent McKoy, and Heung Cheun Choi

Subjects
Shape resonance, Range (particle radiation), Distribution (mathematics), Chemistry, Ionization, Continuum (design consultancy), General Physics and Astronomy, Photoionization, Physical and Theoretical Chemistry, Atomic physics, Symmetry (physics), Ion
Abstract

We present the first measurements of ion rotational distributions for photoionization over an extended range [0 ≤ E_K ≤ 200 eV for N_2 (2σ^(−1)_u ) and 3 ≤ E_K ≤ 125 eV for CO (4σ^(−1))]. The N_2 ion rotational distributions are seen to change dramatically over this energy range, indicating that characteristically molecular behavior of the photoelectron persists far from ionization threshold. In addition, the N_2 and CO results show a strikingly different dependence on energy. Although differences are expected due to the absence of a center of symmetry in CO, detailed calculations reveal that this behavior arises from the presence of Cooper minima in the 2σ_u →kσ_g continuum in the case of N_2 and from an f‐wave shape resonance in the 4σ→kσ channel in CO. Agreement between measured and calculated ion rotational distributions is excellent. The N_2 results are also compared with electron bombardment ionization data. This comparison demonstrates that previous interpretations of electron bombardment data are prone to errors.

Published
1995

38. Excitation of the lowest electronic transitions in ethanol by low-energy electrons

Author

Vincent McKoy, Carl Winstead, Leigh Hargreaves, and Murtadha A. Khakoo

Subjects
Physics, 010304 chemical physics, Scattering, Electron, Condensed Matter Physics, 01 natural sciences, Atomic and Molecular Physics, and Optics, Low energy, Atomic electron transition, Excited state, 0103 physical sciences, Atomic physics, 010306 general physics, Electron ionization, Excitation
Abstract

We report absolute differential and integral cross sections for electronic excitation of ethanol, by low-energy electron impact. Cross sections for low-lying excited states were measured at incident electron energies from 9 to 20 eV and at scattering angles from 5° through 130°. Our results include cross sections for excitation of the 1^3A" and 1^1A" states as well as for the 2^3A"+ 1^3A' and 2^1A" + 2^1A'+ section sums. Corresponding calculations were also performed using the Schwinger multichannel method, within an 11-channel close-coupling scheme.

Published
2016

39. Elastic electron scattering by water molecules

Author

M. A. P. Lima, Vincent McKoy, Lee Mu-Tao, Luiz M. Brescansin, and L. E. Machado

Subjects
Physics, Scattering amplitude, Elastic scattering, Momentum transfer, Scattering length, Optical theorem, Scattering theory, Born approximation, Mott scattering, Atomic physics, Condensed Matter Physics, Atomic and Molecular Physics, and Optics
Abstract

Elastic differential and momentum transfer cross sections are reported for electron scattering by H2O at impact energies ranging from 4 to 50 eV. The iterative Schwinger variational method in the fixed-nuclei, static-exchange approximation is used to calculate the low partial wave scattering amplitudes and the higher partial wave contributions are included via closure using the Born approximation for a point-dipole. Comparison of our calculated cross sections with recent experimental and other theoretical results is encouraging.

Published
1995

40. Threshold Photoelectron Spectroscopy of the A 2.PI. state of CO+

Author

Kwanghsi Wang and Vincent McKoy

Subjects
Autoionization, Chemistry, Ionization, Excited state, Physics::Atomic and Molecular Clusters, General Engineering, Photoionization, Physical and Theoretical Chemistry, Atomic physics, Threshold energy, Ground state, Electron spectroscopy, Ion
Abstract

Results of calculations of single-photon pulsed-field ionization of the 1π orbital of the X ^1Σ^+ (v" = 0) ground state of CO leading to the A Π (v+ = 0-2) excited ionic state are reported. Agreement between the calculated and measured spectra is reasonable except for the A ^2Π_(1/2) (v^+ = 0) level which shows strong autoionization at larger positive ΔJ transitions. Our studies show that the direct photoionization of the In orbital is very atomiclike.

Published
1995

41. Photoion Alignment: Chemical Signatures 200 eV above Threshold

Author

Erwin D. Poliakoff, Chuanyong Wu, Vincent McKoy, Romith Das, Kwanghsi Wang, and A. G. Mihill

Subjects
Shape resonance, Chemistry, Scattering, Oscillator strength, Excited state, Ionization, General Engineering, Molecule, Photoionization, Physical and Theoretical Chemistry, Atomic physics, Threshold energy
Abstract

We present results of experiment and theory for the alignment of CO^+(B^2Σ^+) and N_2^+(B^2Σ^+_u) photoions over an extended energy range (0 ≤ E_k ≤ 210 eV for CO and 0 ≤ E_k ≤ 250 eV for N_2). The polarization of CO^+(B^2Σ^+ → X^2Σ^+) and N_2^+(B^2Σ^+ → X^2Σ^+_g) fluorescence is used to interpret the oscillator strength distributions for normally unresolved degenerate ionization channels. The results show the influence of a CO 4σ → kσ shape resonance clearly and agreement between theory and experiment is excellent. However, agreement between the calculated and measured values is less satisfactory for N_2. This behavior is somewhat surprising, as previous rotationally resolved fluorescence experiments have shown excellent agreement between theory and experiment. This comparison helps to illustrate the complementarity of alignment studies relative to alternative probes of ionization. For both N_2 and CO, the data indicate that the photoions retain significant alignment even at high energies. The results demonstrate that even well above threshold the spectral dependence of the alignment (i.e., polarization) is very sensitive to the molecular environment for photoejection. Such behavior provides useful insight into fundamental scattering phenomena in chemical physics.

Published
1995

42. Ion Distributions for Resonance-Enhanced Multiphoton Ionization of ClO

Author

Vincent McKoy and Kwanghsi Wang

Subjects
Resonance-enhanced multiphoton ionization, Chemistry, Polyatomic ion, General Engineering, Photoionization, Molecular physics, Spectral line, Ion, symbols.namesake, Physics::Atomic and Molecular Clusters, Rydberg formula, symbols, Organic chemistry, Physics::Atomic Physics, Physical and Theoretical Chemistry, Mixing (physics)
Abstract

Results of theoretical studies of rotationally resolved photoelectron spectra for (2 + 1’) resonance enhanced multiphoton ionization (REMPI) of the C ^2Σ^-, D ^2Σ^-, E ^2Σ^-, and F ^2Σ^- Rydberg states of ClO are presented. Cooper minima are predicted to occur in the electronic continua for photoionization of the D and F states and lead to unusual behavior in the ion rotational distributions. Strong partial wave I mixing is also predicted in the continua for the C and E states due to the nonspherical molecular ion potentials. These Cooper minima and l mixing make the associated photoionization dynamics quite nonatomiclike.

Published
1995

43. Parallel computation of electron molecule collisions

Author

Carl Winstead, H. P. Pritchard, and Vincent McKoy

Subjects
Physics, Range (mathematics), symbols.namesake, Parallel processing (DSP implementation), General Engineering, symbols, Concurrent computing, Molecule, Electron, Parallel computing, Massively parallel, Quantum computer, Schrödinger equation
Abstract

The study of collisions between electrons and molecules is an old field, almost as old as the discovery of the electron itself. Yet it has never been a large field; indeed, if we confine our interest (as we do here) to low-energy collisions, only a handful of research groups, experimental or theoretical, are active throughout the world today. It might therefore be appropriate to begin with two questions: Why study such collisions at all? And why is so little research being done?

Published
1995

44. Resonance effects in elastic cross sections for electron scattering on pyrimidine: Experiment and theory

Author

Carl Winstead, Michael Allan, Jimena D. Gorfinkiel, Vincent McKoy, Zdeněk Mašín, and Khrystyna Regeta

Subjects
Shape resonance, 010304 chemical physics, Chemistry, Scattering, General Physics and Astronomy, Resonance, Electron, 01 natural sciences, Cross section (physics), Superposition principle, 0103 physical sciences, Physical and Theoretical Chemistry, Atomic physics, 010306 general physics, Electron scattering, Excitation
Abstract

We measured differential cross sections for elastic (rotationally integrated) electron scattering on pyrimidine, both as a function of angle up to 180∘ at electron energies of 1, 5, 10, and 20 eV and as a function of electron energy in the range 0.1–14 eV. The experimental results are compared to the results of the fixed-nuclei Schwinger variational and R-matrix theoretical methods, which reproduce satisfactorily the magnitudes and shapes of the experimental cross sections. The emphasis of the present work is on recording detailed excitation functions revealing resonances in the excitation process. Resonant structures are observed at 0.2, 0.7, and 4.35 eV and calculations for different symmetries confirm their assignment as the X^2A^2, A^2B_1Ã^2B_1, and B˜2B1B̃2B1 shape resonances. As a consequence of superposition of coherent resonant amplitudes with background scattering the B^2B_1 shape resonance appears as a peak, a dip, or a step function in the cross sections recorded as a function of energy at different scattering angles and this effect is satisfactorily reproduced by theory. The dip and peak contributions at different scattering angles partially compensate, making the resonance nearly invisible in the integral cross section. Vibrationally integrated cross sections were also measured at 1, 5, 10 and 20 eV and the question of whether the fixed-nuclei cross sections should be compared to vibrationally elastic or vibrationally integrated cross section is discussed.

Published
2016

45. Low-energy electron scattering by tetrahydrofuran

Author

Vincent McKoy, A. Gauf, J. Tanner, Leigh Hargreaves, Carl Winstead, Murtadha A. Khakoo, T. Walls, and A. Jo

Subjects
Physics, Elastic scattering, chemistry.chemical_classification, Electron, Polarization (waves), Furanose, Atomic and Molecular Physics, and Optics, chemistry.chemical_compound, Dipole, Low energy, chemistry, Atomic physics, Electron scattering, Tetrahydrofuran
Abstract

Cross sections for elastic scattering of low-energy electrons by tetrahydrofuran, a prototype for the furanose ring found in the backbone of DNA, have been measured and calculated over a wide energy range, with an emphasis on energies below 6 eV, where previous data are scarce. The measurements employ a thin-aperture version of the relative-flow method, while the calculations employ the Schwinger multichannel method with an extensive treatment of polarization effects. Comparisons with earlier results, both experimental and theoretical, are presented and discussed. A proper accounting for the strong permanent electric dipole of tetrahydrofuran is found to be essential to obtaining reliable cross sections, especially at energies below 5 eV.

Published
2012

46. Electronic excitation of silane (SiH4) by low‐energy electron impact

Author

Howard Pritchard, Carl Winstead, and Vincent McKoy

Subjects
chemistry.chemical_compound, Silanes, Scattering, Chemistry, Excited state, General Physics and Astronomy, Singlet state, Physical and Theoretical Chemistry, Atomic physics, Silane, Electron ionization, Dissociation (chemistry), Excitation
Abstract

We report results of a study of the electronic excitation of silane by low‐energy electron impact, including cross sections from 10 to 40 eV impact energy for excitation of the first triplet and singlet excited states (2t2→4sa1)1,3T2. Our results are calculated using the Schwinger multichannel method as implemented for massively parallel computers and include a correction for high‐impact‐parameter excitation of the optically allowed 1T2 transition. We also report values of the total dissociation cross section derived from our calculations and total scattering measurements, and we compare these with direct measurements of the dissociation cross section.

Published
1994

47. Rotationally resolved photoionization of polyatomic hydrides: CH3, H2O, H2S, H2CO

Author

Vincent McKoy, Ralph T. Wiedmann, Michael G. White, and Kwanghsi Wang

Subjects
Angular momentum, Valence (chemistry), Chemistry, Polyatomic ion, Photoionization mode, General Physics and Astronomy, Photoionization, Molecular physics, Atomic orbital, Ionization, Physics::Atomic and Molecular Clusters, Molecular symmetry, Physics::Atomic Physics, Astrophysics::Earth and Planetary Astrophysics, Physics::Chemical Physics, Physical and Theoretical Chemistry, Atomic physics, Astrophysics::Galaxy Astrophysics
Abstract

Combined theoretical and experimental studies of rotationally resolved photoelectron spectra for single‐photon ionization of the outermost valence orbitals of H2O, H2S, H2CO, and CH3 are reported. Agreement between calculated and measured spectra is very encouraging. Both show that photoionization dynamics is very molecular in origin for H2O, H2S, and H2CO but quite atomiclike for CH3. Parity selection rules and the angular momentum composition of the photoelectron are used to illustrate the dynamical aspects of photoionization of polyatomics as molecular symmetry changes in a group of structurally related systems.

Published
1994

48. Rotationally resolved threshold photoelectron spectroscopy of H2O and H2S

Author

Vincent McKoy, Michael G. White, Kwanghsi Wang, Ralph T. Wiedmann, and M.‐T. Lee

Subjects
Angular momentum, X-ray photoelectron spectroscopy, Chemistry, Ionization, Physics::Atomic and Molecular Clusters, General Physics and Astronomy, Matrix element, Photoionization, Physical and Theoretical Chemistry, Atomic physics, Ground state, Ultraviolet radiation, Spectral line
Abstract

We report both measured and calculated rotationally resolved threshold photoelectron spectra for single-photon coherent VUV ionization of the X ^1A_1 ground state of jet-cooled H_2O and H_2S. Agreement between the calculated and measured spectra is very encouraging. Both the H_2O and H_2S spectra show type a transitions which arise from odd angular momentum components of the photoelectron matrix element and are quite molecular in origin. These type a transitions, however, are much weaker in H_2S due to its more atomiclike character.

Published
1994

49. Energy dependence of photoion rotational distributions ofN2and CO

Author

A. G. Mihill, Kwanghsi Wang, Sandeep Kakar, Vincent McKoy, R. M. Rao, Erwin D. Poliakoff, and Heung Cheun Choi

Subjects
Physics, chemistry.chemical_classification, Shape resonance, General Physics and Astronomy, Photoionization, chemistry.chemical_compound, Carbon oxide, chemistry, Excited state, Ionization, Compounds of carbon, Atomic physics, Luminescence, Carbon monoxide
Abstract

We present the first measurements of rotational distributions for photoionization over extended energy ranges [0 ≤ E_k ≤ 200 eV for N_2 (2σ^(-1)_u) and of 3 ≤ E_k ≤ 125 eV for CO (4σ^(−1))]. The N_2 and CO results show a strikingly unusual and different energy dependence. Although differences are expected due to the absence of a center of symmetry in CO, detailed calculations reveal that this behavior arises from the presence of Cooper minima in the photoelectron continuum (kσ_g) in the case of N_2 and from an f-wave shape resonance for 4σ^(−1) photoionization in CO.

Published
1994

50. Rotationally resolved photoelectron spectra in (2 + 1) resonance-enhanced multiphoton ionization of NO via the C 2Π Rydberg state

Author

Kwanghsi Wang, H. Rudolph, and Vincent McKoy

Subjects
Resonance-enhanced multiphoton ionization, Chemistry, General Physics and Astronomy, Photoionization, Laser, Diatomic molecule, Spectral line, law.invention, X-ray photoelectron spectroscopy, law, Ionization, Physics::Atomic Physics, Physical and Theoretical Chemistry, Atomic physics, Rydberg state
Abstract

Results of theoretical studies of rotational branching ratios and photoelectron angular distributions for (2 + 1) resonance-enhanced multiphonon ionization (REMPI) of NO via the Q_(21)(13.5) branch of the C ^2Π(3pπ) Rydberg state are reported and compared with recent measurements. Both calculated and measured spectra reveal that the ΔN=±2 peaks (ee line), which are very weak for the laser polarization parallel to the direction of photoelectron detection, have about 1/4 the intensity of the main ΔN=0 peak when the laser polarizaiton is rotated by 90°. This dependence on laser polarization is due to strong inteference among partial wave components of the photoelectron matrix element. This behavior is very evident in the photoelectron angular distribution. In addition, a Cooper minimum is predicted in the d wave of the 3pπ→Kδ ionization channel.

Published
1994

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