Broad-band structured fluorescence from NaI

Bower, R. D.; Chévrier, P.; Das, Puspendu K.; Foth, Hans‐Jochen; Polanyi, J. C.; Prisant, Michael G.; Visticot, J. P.

doi:10.1063/1.454787

Cited by 24 publications

(22 citation statements)

References 36 publications

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“…58 Figure 7 offers a diagrammatic comparison of the potential energy curve for the fluorescing state determined by FTS with those for the C 0 + state derived from spectroscopic studies in the frequency domain. 33,58 The value of D e ′′′ ) 1863 cm -1 reported here quantitatively accounts for the splitting times obtained at different probe wavelengths as a function of photolysis energy.…”

Section: Fts-based Derivation Of E 2 (R) and E 3 (R)mentioning

confidence: 97%

“…The intense fluorescence monitored by these authors was attributed to bound f bound and bound f free transitions of NaI, which swamped the weak free f bound emission from the [Na‚‚‚1] ‡ * transition states of reaction 1 observed by the same group in separate experiments at shorter photolysis wavelengths. 33,56,57 Bluhm et al have subsequently established the depth of the potential minimum of a state labeled C 0 + leading to the same covalent asymptote by laser excitation spectroscopy across the wavelength range 239 e λ e 256 nm. 43,58 Prior to these two studies, the existence of a state with a shallow potential energy well in the same energy range had only been tentatively inferred from absorption cross section measurements 29 and discussed in relation to an early fluorescence quenching study.…”

Section: Fts-based Derivation Of E 2 (R) and E 3 (R)mentioning

confidence: 99%

“…To demonstrate the robustness of the potentials derived in section III, we have carried out calculations using a Morse curve postulated for E 3 (R). 33 In this case, it was not possible to reproduce satisfactorily the experimental splitting data to quantitative accuracy: values of τ s ) 202 and 96 fs were calculated for λ 2 ) 600 and 640 nm, respectively, at λ 1 ) 320 nm, and τ s ) 225 and 102 fs for the same probe wavelengths at λ 1 ) 360 nm. The periods τ osc remain unchanged from before, of course, since the oscillation frequency depends only upon the λ 1 shape of E 2 (R).…”

Section: Theory: Classical Semiclassical and Quantal Treatmentsmentioning

confidence: 99%

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Femtosecond Real-Time Probing of Reactions. 18. Experimental and Theoretical Mapping of Trajectories and Potentials in the NaI Dissociation Reaction

et al. 1996

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We describe a method of tracking wave packet trajectories by probing both the temporal and spatial evolution of a coherent state prepared by a femtosecond laser pulse in real time. Application to the NaI dissociation reaction illustrates this technique, in which the direction of wave packet propagation within the quasi-bound A 0 + potential is observed and correlated to the physical processes of extension and contraction of the Na-I bond. From the combination of spatial and temporal information observed from experiments, self-consistent potential energy functions for the A 0 + state and the higher-lying state accessed by the probe laser pulse are constructed. The dynamics and the validity of the potentials so derived are tested via semiclassical and quantum-dynamical simulations of the wave packet motion, and comparisons with potentials obtained from other methods are drawn.

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Section: Fts-based Derivation Of E 2 (R) and E 3 (R)mentioning

confidence: 97%

Section: Fts-based Derivation Of E 2 (R) and E 3 (R)mentioning

confidence: 99%

Section: Theory: Classical Semiclassical and Quantal Treatmentsmentioning

confidence: 99%

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Femtosecond Real-Time Probing of Reactions. 18. Experimental and Theoretical Mapping of Trajectories and Potentials in the NaI Dissociation Reaction

et al. 1996

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“…Bluhm et al (5) and Bower et al (6) found a new bound state that leads to one of the Na(3p) asymptotes. Rose et al (7,8) performed femtosecond transition state spectra (FTS) measurements on the reaction of NaI, LiI, and NaBr.…”

Section: Introductionmentioning

confidence: 99%

A configuration interaction study of the ground and first excited ¹∑⁺ states of the NaI molecule

Sakai¹,

Miyoshi²,

Anno³

1992

Can. J. Chem.

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This perper is cledicnrecl to Professor Sigerlt Huzitlcrgn otz the occersiotl of his 65th Dirrt~dc~yYOSHIKO S A K A I , EISAKU MIYOSHI, and TOSINOBU ANNO. Can. J. Chem. 70, 309 (1992).Multireference singly and doubly excited CI (MRSDCI) calculations are performed on the NaI rnolecule by using a model potential method. The potential energy curves of the ground and first excited 'C+ states are generated over a wide range of internuclear distance R . The curves yield the avoided crossing, which is expected to arise by the mixing of the ionic and covalent configurations, and thus the curve of the first excited state shows a shallow minimum. The geometrical parameters, dipole moment. and dissociation energy are calculated. The agreement of those with the experimental results is satisfactory.

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“…The C(0 + ) state can be described by a shallow Morse potential having a dissociation energy between about 500 and 2000 cm -1 . ,, As the probe pulse prepares the C(0 + ) state near its dissociation limit, vibrational relaxation due to collisions with rare-gas atoms might stabilize the NaI molecules below the dissociation limit. Again, argon atoms should result in a larger momentum transfer than helium atoms.…”

Section: Resultsmentioning

confidence: 99%

Femtosecond Time-Resolved Pump−Probe Spectroscopy of NaI in Rare-Gas Environment

et al. 1997

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In this paper we report femtosecond studies of the influence of rare-gas collisions on the dissociation reaction of NaI molecules by investigating the coherent wave packet motion in NaI at a temperature of 670 °C and rare-gas pressures ranging from 0 to 1000 bar. The photodissociation dynamics of NaI is influenced by the interaction between the excited covalent and the ionic ground state potential energy surfaces, which cross at a certain internuclear separation. Due to the adiabaticity of the so formed potential, studies of the elementary nuclear motion and reaction dynamics along the covalent (Na + I) and the ionic (Na+ + I-) channels are possible. The probing is made for the transition-state complex [Na···I]⧧*. Even at low rare-gas pressures a considerable influence of collisions on the wave packet motion within the adiabatic potential well is found. Only few collisions between NaI molecules and surrounding rare-gas atoms result in fast vibrational relaxation and loss of coherence. Furthermore, a stabilization of the transition state is observed due to the decrease of the Landau−Zener escape probability. The reaction cross section for the interaction of the transition state molecules with helium atoms is found to be smaller than for the interaction with argon atoms. The intensity of the detected laser-induced fluorescence arising from the transition Na ← Na* decreases with increasing rare-gas pressure. Here, the effect for argon atoms is smaller than for helium atoms.

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Broad-band structured fluorescence from NaI

Cited by 24 publications

References 36 publications

Femtosecond Real-Time Probing of Reactions. 18. Experimental and Theoretical Mapping of Trajectories and Potentials in the NaI Dissociation Reaction

Femtosecond Real-Time Probing of Reactions. 18. Experimental and Theoretical Mapping of Trajectories and Potentials in the NaI Dissociation Reaction

A configuration interaction study of the ground and first excited ¹∑⁺ states of the NaI molecule

Femtosecond Time-Resolved Pump−Probe Spectroscopy of NaI in Rare-Gas Environment

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Broad-band structured fluorescence from NaI

Cited by 24 publications

References 36 publications

Femtosecond Real-Time Probing of Reactions. 18. Experimental and Theoretical Mapping of Trajectories and Potentials in the NaI Dissociation Reaction

Femtosecond Real-Time Probing of Reactions. 18. Experimental and Theoretical Mapping of Trajectories and Potentials in the NaI Dissociation Reaction

A configuration interaction study of the ground and first excited 1∑+ states of the NaI molecule

Femtosecond Time-Resolved Pump−Probe Spectroscopy of NaI in Rare-Gas Environment

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A configuration interaction study of the ground and first excited ¹∑⁺ states of the NaI molecule