NH2 radical formation by ammonia pyrolysis in a temperature range of 800-1000 K

I. Rahinov; N. Ditzian; S. Cheskis

doi:10.1007/s00340-003-1267-7

NH₂ radical formation by ammonia pyrolysis in a temperature range of 800-1000 K

I. Rahinov, N. Ditzian, S. Cheskis

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

Abstract

The NH₂ radical absolute concentrations were measured using intracavity laser absorption spectroscopy during the process of ammonia pyrolysis at relatively low temperatures of 800-1000 K. The NH₂ spectra have been recorded at pressure of 12-380. The observed absolute concentrations (in the order of ∼ 10¹¹ molecules/cm³) were higher than was predicted by the gas-phase pyrolysis mechanisms. These mechanisms also overestimate the activation energy of the process. The experimental observations can be explained by the existence of an additional channel of NH₂ formation - probably on the surface of the reaction vessel. The addition of oxygen to the reaction mixture causes a considerable (∼ four-fold) increase in the NH₂ radical concentration.

Original language	English
Pages (from-to)	541-546
Number of pages	6
Journal	Applied Physics B: Lasers and Optics
Volume	77
Issue number	5
DOIs	https://doi.org/10.1007/s00340-003-1267-7
State	Published - Oct 2003
Externally published	Yes

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title = "NH2 radical formation by ammonia pyrolysis in a temperature range of 800-1000 K",

abstract = "The NH2 radical absolute concentrations were measured using intracavity laser absorption spectroscopy during the process of ammonia pyrolysis at relatively low temperatures of 800-1000 K. The NH2 spectra have been recorded at pressure of 12-380. The observed absolute concentrations (in the order of ∼ 1011 molecules/cm3) were higher than was predicted by the gas-phase pyrolysis mechanisms. These mechanisms also overestimate the activation energy of the process. The experimental observations can be explained by the existence of an additional channel of NH2 formation - probably on the surface of the reaction vessel. The addition of oxygen to the reaction mixture causes a considerable (∼ four-fold) increase in the NH2 radical concentration.",

author = "I. Rahinov and N. Ditzian and S. Cheskis",

year = "2003",

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doi = "10.1007/s00340-003-1267-7",

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AU - Rahinov, I.

AU - Ditzian, N.

AU - Cheskis, S.

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Y1 - 2003/10

N2 - The NH2 radical absolute concentrations were measured using intracavity laser absorption spectroscopy during the process of ammonia pyrolysis at relatively low temperatures of 800-1000 K. The NH2 spectra have been recorded at pressure of 12-380. The observed absolute concentrations (in the order of ∼ 1011 molecules/cm3) were higher than was predicted by the gas-phase pyrolysis mechanisms. These mechanisms also overestimate the activation energy of the process. The experimental observations can be explained by the existence of an additional channel of NH2 formation - probably on the surface of the reaction vessel. The addition of oxygen to the reaction mixture causes a considerable (∼ four-fold) increase in the NH2 radical concentration.

AB - The NH2 radical absolute concentrations were measured using intracavity laser absorption spectroscopy during the process of ammonia pyrolysis at relatively low temperatures of 800-1000 K. The NH2 spectra have been recorded at pressure of 12-380. The observed absolute concentrations (in the order of ∼ 1011 molecules/cm3) were higher than was predicted by the gas-phase pyrolysis mechanisms. These mechanisms also overestimate the activation energy of the process. The experimental observations can be explained by the existence of an additional channel of NH2 formation - probably on the surface of the reaction vessel. The addition of oxygen to the reaction mixture causes a considerable (∼ four-fold) increase in the NH2 radical concentration.

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JO - Applied Physics B: Lasers and Optics

JF - Applied Physics B: Lasers and Optics

IS - 5

ER -

NH₂ radical formation by ammonia pyrolysis in a temperature range of 800-1000 K

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