Picosecond Rotationally Resolved Stimulated Emission Pumping Spectroscopy of Nitric Oxide

Chakree Tanjaroon, Scott W. Reeve, Alan Ford, W. D. Murry, Kevin Lyon, Bret Yount, Dan Britton, William A. Burns, Susan D. Allen, J. B. Johnson

Research output: Contribution to journalArticlepeer-review

Abstract

Stimulated emission pumping (SEP) experiments were performed on the nitric oxide molecule in a flow cell environment using lasers with pulse widths of 17–25 ps. A lambda excitation scheme, or ‘‘pump– dump’’ arrangement, was employed with the pump laser tuned to the T00 vibronic band origin (kpump ¼ 226:35ð1Þ nm) of the A2 R+ (v0 = 0,J 0 ) X2 P1/2(v00 = 0,J 00) and the dump laser scanned from 246– 248 nm within the A2 R+ (v0 = 0,J 0 ) ? X2 P1/2(v00 = 2,J 00) transition. The rotationally resolved SEP spectra were measured by observing the total fluorescence within the A2 R+ (v0 = 0,J 0 ) ? X2 P1/2(v00 = 1,J 00) transition between 235 nm and 237.2 nm while scanning the dump laser wavelengths. Multiple rotational states were excited due to the broad laser bandwidth. Measurements showed that the resolved rotational structure depended on the energy and bandwidth of the applied pump and dump laser pulses. Analysis of the observed fluorescence depletion signals yielded an average percent fluorescence depletion of about 19% when kpump ¼ 226:35ð1Þ nm and kdump ¼ 247:91ð1Þ nm. This value reflects the percent transfer of the NO population from the A2 R+ (V0 = 0,J 0 ) excited electronic state to the X2 P1/2(v00 = 2,J 00) ground electronic state. The maximum expected depletion is 50% in the limit of dump saturation. Selective excitation of NO at the bandhead provides good spectral discrimination from the background emission and noise and unambiguously confirms the identity of the emitter.
Original languageAmerican English
JournalChemical Physics
Volume393
DOIs
StatePublished - Jan 2012
Externally publishedYes

Keywords

  • picosecond laser
  • nitric oxide
  • stimulated emission pumping
  • flow cell
  • rotational spectrum

Disciplines

  • Atomic, Molecular and Optical Physics

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