OD + CO → D + CO 2 branching kinetics probed with time-resolved frequency comb spectroscopy

@article{Bui2017ODC,
  title={OD + CO → D + CO 2 branching kinetics probed with time-resolved frequency comb spectroscopy},
  author={Thinh Q. Bui and Bryce J Bjork and P. Bryan Changala and Oliver H. Heckl and Benjamin Spaun and Jun Ye},
  journal={Chemical Physics Letters},
  year={2017},
  volume={683},
  pages={91-95}
}
View PDF on arXiv
8 Citations
Background Citations
2
Methods Citations
1

Figures from this paper

8 Citations

Elucidating Reaction Kinetics with Time-Resolved Frequency Comb Spectroscopy

The kinetics of the hydroxyl radical (OH) + carbon monxide (CO) reaction, which is fundamental to both atmospheric and combustion chemistry, are complex because of the formation of the hydrocarboxyl

Direct measurements of DOCO isomers in the kinetics of OD + CO

Time-resolved frequency comb spectroscopy captures real-time dynamics of cis- and trans-DOCO isomers produced from the OD + CO reaction, and comprehensive mechanistic elucidation of the kinetics of the isotopic analog deuteroxyl radical (OD) with CO has been realized.

Spectral analyses of trans- and cis-DOCO transients via comb spectroscopy

ABSTRACT We use time-resolved direct frequency comb spectroscopy in the mid-infrared to obtain high-resolution rovibrational spectra of products produced from the OD + CO reaction. In this work, we

Single-Shot Sub-microsecond Mid-infrared Spectroscopy on Protein Reactions with Quantum Cascade Laser Frequency Combs.

A single shot is sufficient to extract spectral and kinetic characteristics of several intermediates in the bacteriorhodopsin photocycle and paves the way for the noninvasive analysis of enzymatic conversions with high time resolution, broad spectral coverage, and minimal sample consumption.

Quantitative modeling of complex molecular response in coherent cavity-enhanced dual-comb spectroscopy.

Monte Carlo stochastic simulation of the master equation for unimolecular reaction systems

  • J. Barker
  • Physics
    Unimolecular Kinetics - Parts 2 and 3: Collisional Energy Transfer and The Master Equation
  • 2019

Experimental Studies of Gas-Phase Reactivity in Relation to Complex Organic Molecules in Star-Forming Regions

The field of astrochemistry concerns the formation and abundance of molecules in the interstellar medium, star-forming regions, exoplanets, and solar system bodies. These astrophysical objects cont...

Semiclassical transition state theory/master equation kinetics of HO + CO: Performance evaluation

References

SHOWING 1-10 OF 41 REFERENCES

Mid-Infrared Time-Resolved Frequency Comb Spectroscopy of Transient Free Radicals.

Time-resolved frequency comb spectroscopy (TRFCS) is demonstrated, a new broadband absorptionSpectroscopy technique for the study of trace free radicals on the microsecond timescale that allows for the unraveling of primary and secondary chemical reaction pathways.

Rate Constant for the OH + CO Reaction at Low Temperatures.

Rate constants for the reaction of OH + CO → products (1) have been measured using laser photolysis/laser-induced fluorescence (LP/LIF) over the temperature range 193–296 K and at pressures of 50–700

High pressure range of addition reactions of HO. II. Temperature and pressure dependence of the reaction HO+CO⇔HOCO→H+CO2

Thermal rate constants of the complex‐forming bimolecular reaction HO+CO■HOCO→H+CO2 were measured between 90 and 830 K in the bath gas He over the pressure range 1–700 bar. In addition, the

ESR Intensity Relations and Some Gas‐Phase Chemical Kinetics of the OD Radical

The theoretical intensity relations for the quantitative determination of gas‐phase OD radical and D atom concentrations by ESR spectroscopy are derived. OD was generated by the fast reaction of D

The pressure dependence of the rate constant of the reaction of OD radicals with CO

Reaction of HO with CO: Tunneling Is Indeed Important.

The role of quantum tunneling is confirmed to be extremely important, which supports recent work by Continetti and collaborators regarding the loss of hydrogen atoms from vibrationally excited states of HOCO.

Rate measurements of reactions of OH by resonance absorption. Part 2.—Reactions of OH with CO, C2H4 and C2H2

The rates of the reactions of OH with CO, C2H4 and C2H2 have been determined between 210 K and 460 K using time-resolved resonance absorption to monitor the removal of OH radicals following their

Reaction between hydroxyl (deuteroxyl) radicals and carbon monoxide at temperatures down to 80 K: experiment and theory

Using the pulsed laser-photolysis (PLP) laser-induced fluorescence (LIF) method, rate constants have been measured at low total pressure for the reactions between OH and CO (297≥T/K≥80) and OD+CO

Energy and structure of the transition states in the reaction OH + CO → H + CO2

Two, quite different, experimental studies have been carried out on the reaction between OH and CO at low total pressures. In the first, rate constants have been determined at 82 and 106 K. At the

The pressure dependence of the rate constant of the reaction of OH radicals with CO

Absolute rate constants for the reaction OH+CO+M have been determined in the gas phase, at 298 K, in the pressure range 20–700 Torr of He, N2, CF4, and SF6 and 0–20 Torr of H2O. Hydroxyl radicals