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In situ infrared emission spectroscopy for quantitative gas-phase measurement under high temperature reaction conditions: an analytical method for methane by means of an innovative small-volume flowing cell.

Authors :
Usseglio S
Thorshaug K
Karlsson A
Dahl IM
Nielsen CJ
Jens KJ
Tangstad E
Source :
Applied spectroscopy [Appl Spectrosc] 2010 Feb; Vol. 64 (2), pp. 141-8.
Publication Year :
2010

Abstract

We have used infrared emission spectroscopy (IRES) in order to perform in situ studies under flowing gas-phase conditions. When the small-volume cell developed herein is used, we can (1) observe emission spectra from a hot gas-phase sample having an effective volume much less than one milliliter, (2) observe spectra of typical molecular species present, and (3) observe spectra of the more important molecular species down to below 10% and in some cases even as low as 1%. In addition, an analytical method has been derived in order to conduct quantitative studies under typical reaction conditions. We show that simplifications can be made in the data acquisition and handling for a direct linear correlation between band intensity and concentration with only simple background correction. The practical lower limit for methane in the present setup is approximately 0.5-1% v/v depending on the selected temperature. Our data were collected at 500, 600, and 700 degrees C, respectively. The major features of the present cell design are fairly simple and basically formed by a quartz tube (outer diameter=6 mm, inner diameter=4 mm) inside a metal pipe and two tubular ceramic heaters. This simple setup has advantages and attractive features that have extended the application of IRES to new fields and, in particular, for in situ studies of hydrocarbon reactions at different residence times at high temperature.

Details

Language :
English
ISSN :
1943-3530
Volume :
64
Issue :
2
Database :
MEDLINE
Journal :
Applied spectroscopy
Publication Type :
Academic Journal
Accession number :
20149274
Full Text :
https://doi.org/10.1366/000370210790619564