Vacuum-Ultraviolet Photochemistry. IX. Primary and Chain Processes in the Photolysis of Hydrogen Peroxide

Abstract

Evidence is presented for the occurrence of primary processes leading to the formation of both atomic and molecular hydrogen in the photolysis of H2O2 at 1236 Å. Formation of OH in a primary process probably occurs as well. The latter is apparently the sole process required to explain the results at 1470 and 2537 Å. Processes leading to the formation of O(1D) account for less than 1% of the photochemical decomposition. Chain processes leading to the formation of O2 but not H2 occur at 1236 Å. The possibilities considered are a free radical chain and an energy chain. It is shown that the results are more consistent with the occurrence of an energy chain involving atomic hydrogen and vibrationally excited OH radicals. Emission of OH A 2Σ+→X2II(0, 0) band at 3064 Å was observed during photolysis of H2O2 at 1236 and 1470 Å.

References

Page 1

	Year	Citations
Combustion, flames and explosion of gases Dr.J. van Steenis Chemical Engineering Science EngineeringCombustion ScienceCombustion TheoryHeterogeneous CombustionChemical Kinetics	1952	301
Mass Spectrometry of the HO2 Free Radical S. N. Foner, Reggie L. Hudson The Journal of Chemical Physics Radical EmissionEngineeringMass SpectrometerBiological Mass SpectrometryHo2 Radicals	1962	191
Intense Resonance Line Sources for Photochemical Work in the Vacuum Ultraviolet Region H. Okabe Journal of the Optical Society of America Ultraviolet LightX-ray SpectroscopyEngineeringAtomic Emission SpectroscopyVacuum Ultraviolet Region	1964	122
Collisional Deactivation of the Excited Singlet Oxygen Atoms and Their Insertion into the CH Bonds of Propane Hideo Yamazaki, R. J. Cvetanović The Journal of Chemical Physics Localized Excited StateEngineeringCombustion TheoryExcited AtomsChemistry	1964	118
THE ABSORPTION SPECTRUM AND DECOMPOSITION OF HYDROGEN PEROXIDE BY LIGHT Harold C. Urey, L. H. Dawsey, F. O. Rice Journal of the American Chemical Society Ultraviolet LightEngineeringChemical AnalysisAltmetric Attention ScoreAbsorption Spectroscopy	1929	113
Vacuum Ultraviolet Photochemistry. III. Primary Processes in the Vacuum Ultraviolet Photolysis of Water and Ammonia J. R. McNesby, Ikuzo Tanaka, H. Okabe The Journal of Chemical Physics Ultraviolet LightEngineeringAtmospheric PhotochemistryChemistryEnvironmental Photochemistry	1962	98
The thermal decomposition of hydrogen peroxide vapour D. E. Hoare, J. B. Protheroe, A. D. Walsh Transactions of the Faraday Society Chemical EngineeringHumanitiesEngineeringThermal DecompositionThermal Catalysis	1959	90
Effect of Temperature on the Vacuum Ultraviolet Transmittance of Lithium Fluoride, Calcium Fluoride, Barium Fluoride, and Sapphire* Allan H. Laufer, J. A. Pirog, J. R. McNesby Journal of the Optical Society of America Ultraviolet LightShort Wavelength OpticOptical MaterialsVacuum Ultraviolet TransmittanceEngineering	1965	80
Rate of Reaction in Hydrogen, Nitrous Oxide and in Some Other Flames C.P. Fenimore, Gary Jones The Journal of Physical Chemistry Laminar FlameChemical EngineeringNitrous OxideEngineeringChemical Measurement	1959	77
Photolysis of Carbon Dioxide Bruce H. Mahan The Journal of Chemical Physics Carbon DioxidePhotorespirationHealth SciencesPhysicsPhotochemistry	1960	72

Page 1