Rovibrational energy transfer in the 4vCH manifold of acetylene, viewed by IR-UV double resonance spectroscopy. 1. Foundation studies at low J

Mark A. Payne; Angela P. Milce; Michael J. Frost; Brian J. Orr

doi:10.1021/jp035224t

Rovibrational energy transfer in the 4v_CH manifold of acetylene, viewed by IR-UV double resonance spectroscopy. 1. Foundation studies at low J

Mark A. Payne, Angela P. Milce, Michael J. Frost, Brian J. Orr^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

15 Citations (Scopus)

Abstract

Time-resolved infrared-ultraviolet double resonance (IR-UV DR) spectroscopy is used to prepare acetylene molecules (C₂H₂) in specific rovibrational states of the 12 700 cm^-1 4v_CH manifold of the electronic groundstate X̃, monitoring their direct excitation and collision-induced state-to-state energy transfer, by probing at ∼299 or ∼296 nm with laser-induced fluorescence via the Ã electronic state. The 4v_CH manifold derives much of its IR brightness from the (v₁ + 3v₃) combination band, such that many of the rotational levels J monitored by IR-UV DR are derived from the (1 0 3 0 0)⁰ vibrational state. The 4v_CH manifold of C₂H₂ is congested and affected by anharmonic, l-resonance, and Coriolis couplings that cause other IR-dark, UV-bright rovibrational levels to attain appreciable IR-UV DR intensity and to add to the complexity of intramolecular dynamics in that manifold. Consequently, collision-induced rovibrational satellites observed by IR-UV DR comprise not only regular even-ΔJ features but also supposedly forbidden odd-ΔJ features, of which the energy-transfer channel from J = 12 to J = 1 is particularly efficient. This paper focuses on low-J rovibrational levels of the 4v_CH manifold, particularly those with J = 0 and J = 1 in view of their anomalously large Stark effects that are likely to make them susceptible to collision-induced rovibrational mixing. Three complementary forms of IR-UV DR experiment are reported: IR-scanned, UV-scanned, and kinetic. These indicate that strong IR-UV DR signals observed by probing the (1 0 3 0 0)⁰ J = 0 rovibrational level are complicated by underlying IR-dark, UV-bright states, making J = 0 unsuitable for systematic IR-UV DR studies. The (1 0 3 0 0)⁰ J = 1 rovibrational level is more amenable to unambiguous characterization and yields insight concerning even- and odd-ΔJ collision-induced rovibrational energy transfer and associated mechanisms.

Original language	English
Pages (from-to)	10759-10770
Number of pages	12
Journal	Journal of Physical Chemistry A
Volume	107
Issue number	49
DOIs	https://doi.org/10.1021/jp035224t
Publication status	Published - 11 Dec 2003

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@article{3d89dd4ed58946caa94876a196e695ca,

title = "Rovibrational energy transfer in the 4vCH manifold of acetylene, viewed by IR-UV double resonance spectroscopy. 1. Foundation studies at low J",

abstract = "Time-resolved infrared-ultraviolet double resonance (IR-UV DR) spectroscopy is used to prepare acetylene molecules (C2H2) in specific rovibrational states of the 12 700 cm-1 4vCH manifold of the electronic groundstate {\~X}, monitoring their direct excitation and collision-induced state-to-state energy transfer, by probing at ∼299 or ∼296 nm with laser-induced fluorescence via the {\~A} electronic state. The 4vCH manifold derives much of its IR brightness from the (v1 + 3v3) combination band, such that many of the rotational levels J monitored by IR-UV DR are derived from the (1 0 3 0 0)0 vibrational state. The 4vCH manifold of C2H2 is congested and affected by anharmonic, l-resonance, and Coriolis couplings that cause other IR-dark, UV-bright rovibrational levels to attain appreciable IR-UV DR intensity and to add to the complexity of intramolecular dynamics in that manifold. Consequently, collision-induced rovibrational satellites observed by IR-UV DR comprise not only regular even-ΔJ features but also supposedly forbidden odd-ΔJ features, of which the energy-transfer channel from J = 12 to J = 1 is particularly efficient. This paper focuses on low-J rovibrational levels of the 4vCH manifold, particularly those with J = 0 and J = 1 in view of their anomalously large Stark effects that are likely to make them susceptible to collision-induced rovibrational mixing. Three complementary forms of IR-UV DR experiment are reported: IR-scanned, UV-scanned, and kinetic. These indicate that strong IR-UV DR signals observed by probing the (1 0 3 0 0)0 J = 0 rovibrational level are complicated by underlying IR-dark, UV-bright states, making J = 0 unsuitable for systematic IR-UV DR studies. The (1 0 3 0 0)0 J = 1 rovibrational level is more amenable to unambiguous characterization and yields insight concerning even- and odd-ΔJ collision-induced rovibrational energy transfer and associated mechanisms.",

author = "Payne, {Mark A.} and Milce, {Angela P.} and Frost, {Michael J.} and Orr, {Brian J.}",

year = "2003",

month = dec,

day = "11",

doi = "10.1021/jp035224t",

language = "English",

volume = "107",

pages = "10759--10770",

journal = "Journal of Physical Chemistry A",

issn = "1089-5639",

publisher = "AMER CHEMICAL SOC",

number = "49",

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T1 - Rovibrational energy transfer in the 4vCH manifold of acetylene, viewed by IR-UV double resonance spectroscopy. 1. Foundation studies at low J

AU - Payne, Mark A.

AU - Milce, Angela P.

AU - Frost, Michael J.

AU - Orr, Brian J.

PY - 2003/12/11

Y1 - 2003/12/11

N2 - Time-resolved infrared-ultraviolet double resonance (IR-UV DR) spectroscopy is used to prepare acetylene molecules (C2H2) in specific rovibrational states of the 12 700 cm-1 4vCH manifold of the electronic groundstate X̃, monitoring their direct excitation and collision-induced state-to-state energy transfer, by probing at ∼299 or ∼296 nm with laser-induced fluorescence via the Ã electronic state. The 4vCH manifold derives much of its IR brightness from the (v1 + 3v3) combination band, such that many of the rotational levels J monitored by IR-UV DR are derived from the (1 0 3 0 0)0 vibrational state. The 4vCH manifold of C2H2 is congested and affected by anharmonic, l-resonance, and Coriolis couplings that cause other IR-dark, UV-bright rovibrational levels to attain appreciable IR-UV DR intensity and to add to the complexity of intramolecular dynamics in that manifold. Consequently, collision-induced rovibrational satellites observed by IR-UV DR comprise not only regular even-ΔJ features but also supposedly forbidden odd-ΔJ features, of which the energy-transfer channel from J = 12 to J = 1 is particularly efficient. This paper focuses on low-J rovibrational levels of the 4vCH manifold, particularly those with J = 0 and J = 1 in view of their anomalously large Stark effects that are likely to make them susceptible to collision-induced rovibrational mixing. Three complementary forms of IR-UV DR experiment are reported: IR-scanned, UV-scanned, and kinetic. These indicate that strong IR-UV DR signals observed by probing the (1 0 3 0 0)0 J = 0 rovibrational level are complicated by underlying IR-dark, UV-bright states, making J = 0 unsuitable for systematic IR-UV DR studies. The (1 0 3 0 0)0 J = 1 rovibrational level is more amenable to unambiguous characterization and yields insight concerning even- and odd-ΔJ collision-induced rovibrational energy transfer and associated mechanisms.

AB - Time-resolved infrared-ultraviolet double resonance (IR-UV DR) spectroscopy is used to prepare acetylene molecules (C2H2) in specific rovibrational states of the 12 700 cm-1 4vCH manifold of the electronic groundstate X̃, monitoring their direct excitation and collision-induced state-to-state energy transfer, by probing at ∼299 or ∼296 nm with laser-induced fluorescence via the Ã electronic state. The 4vCH manifold derives much of its IR brightness from the (v1 + 3v3) combination band, such that many of the rotational levels J monitored by IR-UV DR are derived from the (1 0 3 0 0)0 vibrational state. The 4vCH manifold of C2H2 is congested and affected by anharmonic, l-resonance, and Coriolis couplings that cause other IR-dark, UV-bright rovibrational levels to attain appreciable IR-UV DR intensity and to add to the complexity of intramolecular dynamics in that manifold. Consequently, collision-induced rovibrational satellites observed by IR-UV DR comprise not only regular even-ΔJ features but also supposedly forbidden odd-ΔJ features, of which the energy-transfer channel from J = 12 to J = 1 is particularly efficient. This paper focuses on low-J rovibrational levels of the 4vCH manifold, particularly those with J = 0 and J = 1 in view of their anomalously large Stark effects that are likely to make them susceptible to collision-induced rovibrational mixing. Three complementary forms of IR-UV DR experiment are reported: IR-scanned, UV-scanned, and kinetic. These indicate that strong IR-UV DR signals observed by probing the (1 0 3 0 0)0 J = 0 rovibrational level are complicated by underlying IR-dark, UV-bright states, making J = 0 unsuitable for systematic IR-UV DR studies. The (1 0 3 0 0)0 J = 1 rovibrational level is more amenable to unambiguous characterization and yields insight concerning even- and odd-ΔJ collision-induced rovibrational energy transfer and associated mechanisms.

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DO - 10.1021/jp035224t

M3 - Article

AN - SCOPUS:0347516329

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JO - Journal of Physical Chemistry A

JF - Journal of Physical Chemistry A

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ER -

Rovibrational energy transfer in the 4v_CH manifold of acetylene, viewed by IR-UV double resonance spectroscopy. 1. Foundation studies at low J

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