Photoelectron spectroscopic studies of multiphoton processes in molecular chlorine involving the 2 1∏<i>g</i> Rydberg state

Koenders, B.G.; Koeckhoven, S. M.; Kuik, G.J.; Drabe, Karel E.; Lange, C.A. de

doi:10.1063/1.457422

Cited by 22 publications

(18 citation statements)

References 56 publications

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“…Very good agreement was found for the angular and kinetic-energy distributions measured in the two different laboratories using velocity map imaging. Good agreement is also found for the photoelectron kinetic-energy distributions obtained from the images and those reported by Koenders et al 5 for the same intermediate states.…”

Section: Resultssupporting

confidence: 87%

“…The goal of this study is to experimentally determine how Cl ϩ is formed and in the process gain more information on the photodynamics of Cl 2 and Cl 2 ϩ . Koenders et al 5 have determined the primary photophysical processes for the most common REMPI detection scheme for Cl 2 , which takes place using two-photon excitation through the vϭ0 -15 vibrational levels of the 2 1 ⌸ g (4s) Rydberg state. Following their discussion, the Cl 2 excitation process and the relevant electronic states involved are shown schematically in Fig.…”

Section: Introductionmentioning

confidence: 99%

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Photodissociation–ionization dynamics of molecular chlorine Rydberg states using velocity map imaging

Parker

Баккер

Samartzis

et al. 2001

The Journal of Chemical Physics

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A critical re-assignment of the Rydberg states of iodomethane based on new polarization data Photoelectron and photofragment velocity map imaging of state-selected molecular oxygen dissociation/ionization dynamics Velocity map images are reported for photoelectrons and atomic chlorine ions produced during one-color REMPI ͑resonance enhanced multiphoton ionization͒ of molecular chlorine via the v ϭ0 -15 vibrational levels of the 2 1 ⌸ g (4s) Rydberg state. Previous magnetic bottle photoelectron studies by Koenders et al. of the same process have shown that REMPI proceeds by two-photon resonant excitation, followed by core-excitation to a super-excited Rydberg state at the three-photon level. This state undergoes ͑auto͒-ionization, resulting in the formation of ground-state molecular chlorine ions, and/or dissociation to neutral products, resulting in the production of electronically excited neutral chlorine atoms. Photoelectrons arise from ionization of Cl 2 and electronically excited Cl atoms, while Cl ϩ ions arise from the dissociation of Cl 2 ϩ and from ionization of the excited Cl atoms. The chlorine ion velocity map images reveal new information on the dissociation-ionization dynamics of superexcited Cl 2 and the dissociation dynamics of the subsequently formed Cl 2 ϩ ions. In the latter case an unexpected low-energy ⌺←⌸ ͑perpendicular͒ dissociation pathway to Cl ϩ ( 1 D)ϩCl( 3 P) product atoms is observed. Results from the photoelectron images are compared with those from the magnetic bottle studies. While the imaging kinetic-energy resolution is less than that of the magnetic bottle spectrometer, the angular distribution information and lack of velocity bias of imaging is advantageous. Most of the trends observed in the electron and Cl ϩ images can be rationalized in terms of single-electron excitation processes and the known molecular orbital structure of the electronic states involved.

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Section: Resultssupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Photodissociation–ionization dynamics of molecular chlorine Rydberg states using velocity map imaging

Parker

Баккер

Samartzis

et al. 2001

The Journal of Chemical Physics

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“…The strong progression is due to the ͓ 2 ⌸ 1/2 ͔ c 4s; 1 g Rydberg state. Isotopic shifts confirm the previous assignment 12,13 of the origin at 64 026 cm Ϫ1 . Vibrational levels up to vЈϭ19 were observed ͑see also Fig.…”

Section: (2؉1) Rempi Studies Of the Rydberg Statessupporting

confidence: 78%

“…Koenders et al 13 simulated the bandhead contours of the ͑2,0͒ and ͑5,0͒ bands of the ͓ 2 ⌸ 1/2 ͔ c 4s; 1 g Rydberg state in the ͑2ϩ1͒ REMPI spectrum of Cl 2 . B values were obtained, from which ␣ e , B e , and R e were estimated.…”

Section: A Potential Energy Curvesmentioning

confidence: 99%

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Mass-resolved multiphoton ionization spectroscopy of jet-cooled Cl2. I. Bound-free-bound spectroscopy

Al-Kahali

Donovan

Lawley

et al. 1996

The Journal of Chemical Physics

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Spectroscopic constants, obtained using two-color optical double resonance via repulsive intermediate states, are presented for four ion-pair states of Cl 2 ; i.e., the E(0 g ϩ ), ␤͑1 g ͒, f (0 g ϩ ), and G(1 g ) states. One-color excitation, also via a repulsive intermediate state, has been used to further extend the vibrational data for the ␤͑1 g ͒ state. The same pumping scheme has been used to extend a vibrational progression in the ͓ 2 ⌸ 1/2 ͔ c 4s; 1 g Rydberg state. The absence of perturbations when the ͓ 2 ⌸ 1/2 ͔ c 4s; 1 g Rydberg and the ␤͑1 g ͒ ion-pair states cross, together with the key role played by the intermediate C(1 u ) state in accessing both singlet and triplet final states, are discussed in terms of the changes in spin-orbital coupling schemes that are required on bond stretching.

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Multiphoton Ionization State Selection: Vibrational‐Mode and Rotational‐State Control

Anderson

1992

Advances in Chemical Physics

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Photoelectron spectroscopic studies of multiphoton processes in molecular chlorine involving the 2 1∏g Rydberg state

Cited by 22 publications

References 56 publications

Photodissociation–ionization dynamics of molecular chlorine Rydberg states using velocity map imaging

Photodissociation–ionization dynamics of molecular chlorine Rydberg states using velocity map imaging

Mass-resolved multiphoton ionization spectroscopy of jet-cooled Cl2. I. Bound-free-bound spectroscopy

Multiphoton Ionization State Selection: Vibrational‐Mode and Rotational‐State Control

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