Chang Zhou scite author profile

The fine structure resolved photofragment O(-)((2)P(j)) image from the O(2) ion-pair production at 17.499 eV has been recorded. The branching ratio for producing the low energy spin-orbit O(-)((2)P(3/2)) component to the high energy spin-orbit O(-)((2)P(1/2)) component is 1:0.78 and the optical transitions for them correspond to perpendicular and parallel transitions, respectively. The anisotropy parameters, 1.64 for channel producing O(-)((2)P(1/2)) and -0.35 for O(-)((2)P(3/2)), suggest that the dissociation proceeds via the states with symmetry (3)Sigma(u)(-) and (3)Pi(u), respectively. Although the main mechanisms for the O(2) ion-pair production are the predissociation via the intermediate Rydberg states, the direct dissociation mechanism for the channel producing O(-)((2)P(1/2)) may also be involved.

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A combined zero electronic kinetic energy spectroscopy and ion-pair dissociation imaging study of the F2+(XΠg2) structure

Yang

Hao

et al. 2005

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Rotationally resolved pulsed field ionization and zero electronic kinetic energy photoelectron spectra for the transition F(2) (+)(X (2)Pi(g))<--F(2)(X (1)Sigma(g) (+)) have been recorded using the extreme ultraviolet coherence radiation. The vibrational energy spacings, rotational constants, and spin orbit coupling constants for the first three vibrational states of F(2) (+)(X (2)Pi(g)) have been determined accurately. The first adiabatic ionization potential (IP) of F(2) is determined as IP(F(2))=126 585.7+/-0.5 cm(-1). To determine the threshold E(tipp) for ion-pair production of F(2), the images of F(-)((1)S(0)) in the velocity mapping conditions have also been recorded at the photon energy of 126 751 cm(-1). Taking the Stark effect into account, the E(tipp) is determined as E(tipp)(F(2))=126 045+/-8 cm(-1) (15.628+/-0.001 eV). By combing the IP(F(2)) and the E(tipp)(F(2)) determined in this work and together with the reported ionization potential and electronic affinity of the F atom, the bond dissociation energies of F(2) and F(2) (+) are determined as D(0)(F(2))=1.606+/-0.001 eV and D(0)(F(2) (+))=3.334+/-0.001 eV, respectively.

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Vibrational structure, spin-orbit splitting, and bond dissociation energy of Cl2+(X̃Πg2) studied by zero kinetic energy photoelectron spectroscopy and ion-pair formation imaging method

Hao

Yang

et al. 2007

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The isotopomer-resolved vibrational and spin-orbit energy structures of Cl(2) (+)(X (2)Pi(g)) have been studied by one-photon zero kinetic energy photoelectron spectroscopy. The spin-orbit energy splitting for the ground vibrational state is determined as 717.7+/-1.5 cm(-1), which greatly improves on the accuracy of the previously reported data. This value is found to be in good agreement with the ab initio quantum chemical calculation taking account of the inner shell electron correlation. The first adiabatic ionization energy (IE) of Cl(2) is determined as 92 645.9+/-1.0 cm(-1). Using the ion-pair formation imaging method to discriminate signals of Cl(+)((1)D(2)) from those of Cl(+)((3)P(j)), the threshold for ion-pair (E(tipp)) production, Cl(+)((1)D(2))+Cl(-)((1)S(0))<--Cl(2)(X (1)Sigma(g) (+)), is determined as 107 096(-2) (+8) cm(-1). By using the determined IE and E(tipp) for Cl(2) and also the reported IE and electronic affinity for chlorine atom, the bond dissociation energies of Cl(2)(X (1)Sigma(g) (+)) and Cl(2) (+)(X (2)Pi(g)) have been determined as 19 990(-2) (+8) and 31 935.1(-2) (+8), respectively.

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The Jahn−Teller Effect in CH₃CN⁺ (X̃²E) and CD₃CN⁺ (X̃²E) Studied by Zero Kinetic Energy Photoelectron Spectroscopy

Yang

Zhou

2005

J. Phys. Chem. A

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The Jahn-Teller effect in CH(3)CN(+) (X(2)E) and CD(3)CN(+) (X(2)E) has been found experimentally by zero kinetic energy (ZEKE) photoelectron spectroscopy using coherent extreme ultraviolet (XUV) radiation. The vibronic bands of CH(3)CN(+) (X(2)E) and CD(3)CN(+) (X(2)E) at about 4500 cm(-1) above the ground states have been recorded. The spectra consist mainly of the Jahn-Teller active C-C[triple bond]N bending (v(8)), the CN stretching (v(2)), the CH(3) (CD(3)) deforming (v(6)), and the C-C stretching (v(4)) vibronic excitations. The Jahn-Teller active vibronic bands (v(8)) have been assigned with a harmonic model including linear and quadratic Jahn-Teller coupling terms, taking into account only the single mode vibronic excitation. The ionization potentials of CH(3)CN and CD(3)CN have also been determined, and their values are 12.2040(+/-0.001) and 12.2286(+/-0.001) eV, respectively.

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Chang Zhou

Erratum: “A combined zero electronic kinetic energy spectroscopy and ion-pair dissociation imaging study of the F2+(X∏g2) structure” [J. Chem. Phys. 122, 134308 (2005)]

Velocity Map Imaging Study of the O₂ Ion-Pair Production at 17.499 eV: Simultaneous Parallel and Perpendicular Transitions

A combined zero electronic kinetic energy spectroscopy and ion-pair dissociation imaging study of the F2+(XΠg2) structure

Vibrational structure, spin-orbit splitting, and bond dissociation energy of Cl2+(X̃Πg2) studied by zero kinetic energy photoelectron spectroscopy and ion-pair formation imaging method

The Jahn−Teller Effect in CH₃CN⁺ (X̃²E) and CD₃CN⁺ (X̃²E) Studied by Zero Kinetic Energy Photoelectron Spectroscopy

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Chang Zhou

Erratum: “A combined zero electronic kinetic energy spectroscopy and ion-pair dissociation imaging study of the F2+(X∏g2) structure” [J. Chem. Phys. 122, 134308 (2005)]

Velocity Map Imaging Study of the O2 Ion-Pair Production at 17.499 eV: Simultaneous Parallel and Perpendicular Transitions

A combined zero electronic kinetic energy spectroscopy and ion-pair dissociation imaging study of the F2+(XΠg2) structure

Vibrational structure, spin-orbit splitting, and bond dissociation energy of Cl2+(X̃Πg2) studied by zero kinetic energy photoelectron spectroscopy and ion-pair formation imaging method

The Jahn−Teller Effect in CH3CN+ (X̃2E) and CD3CN+ (X̃2E) Studied by Zero Kinetic Energy Photoelectron Spectroscopy

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Velocity Map Imaging Study of the O₂ Ion-Pair Production at 17.499 eV: Simultaneous Parallel and Perpendicular Transitions

The Jahn−Teller Effect in CH₃CN⁺ (X̃²E) and CD₃CN⁺ (X̃²E) Studied by Zero Kinetic Energy Photoelectron Spectroscopy