Integrating cavity based gas cells: a multibeam compensation scheme for pathlength variation
Optics Express, 2016•opg.optica.org
We present a four beam ratiometric setup for an integrating sphere based gas cell, which
can correct for changes in pathlength due to sphere wall contamination. This allows for the
gas absorption coefficient to be determined continuously without needing to recalibrate the
setup. We demonstrate the technique experimentally, measuring methane gas at 1651nm.
For example, contamination covering 1.2% of the sphere wall resulted in an uncompensated
error in gas absorption coefficient of≈ 41%. With the ratiometric scheme, this error was …
can correct for changes in pathlength due to sphere wall contamination. This allows for the
gas absorption coefficient to be determined continuously without needing to recalibrate the
setup. We demonstrate the technique experimentally, measuring methane gas at 1651nm.
For example, contamination covering 1.2% of the sphere wall resulted in an uncompensated
error in gas absorption coefficient of≈ 41%. With the ratiometric scheme, this error was …
We present a four beam ratiometric setup for an integrating sphere based gas cell, which can correct for changes in pathlength due to sphere wall contamination. This allows for the gas absorption coefficient to be determined continuously without needing to recalibrate the setup. We demonstrate the technique experimentally, measuring methane gas at 1651nm. For example, contamination covering 1.2% of the sphere wall resulted in an uncompensated error in gas absorption coefficient of ≈41%. With the ratiometric scheme, this error was reduced to ≈2%. Potential limitations of the technique, due to subsequent deviations from mathematical assumptions are discussed, including severe sphere window contamination.
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