A new photometric ozone reference in the Huggins bands: the absolute ozone absorption cross section at the 325 nm HeCd laser wavelength

The room temperature (294.09 K) absorption cross section of ozone at the 325 nm HeCd wavelength has been determined under careful consideration of possible biases. At the vacuum wavelength of 325.126 nm, thus in a region used by a variety of ozone remote sensing techniques, an absorption cross-secti...

Full description

Saved in:
Bibliographic Details
Published in:Atmospheric measurement techniques 2018-03, Vol.11 (3), p.1707-1723
Main Authors: Janssen, Christof, Elandaloussi, Hadj, Gröbner, Julian
Format: Article
Language:English
Subjects:
Absorption
Absorption by ozone
Absorption cross sections
Absorption spectra
Accuracy
Astrophysics
Atmospheric and Oceanic Physics
Atmospheric ozone
Atomic and Molecular Clusters
Breweries
Cold
Decomposition
Detection
Environmental aspects
Gases
Lasers
Measurement
Ozone
Photometry
Physics
Remote sensing
Remote sensing techniques
Room temperature
Sensing techniques
Spectra
Temperature
Ultraviolet radiation
Uncertainty
Vacuum
Wavelength
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The room temperature (294.09 K) absorption cross section of ozone at the 325 nm HeCd wavelength has been determined under careful consideration of possible biases. At the vacuum wavelength of 325.126 nm, thus in a region used by a variety of ozone remote sensing techniques, an absorption cross-section value of σ = 16.470×10−21 cm2 was measured. The measurement provides the currently most accurate direct photometric absorption value of ozone in the UV with an expanded (coverage factor k = 2) standard uncertainty u(σ) = 31×10−24 cm2, corresponding to a relative level of 2 ‰. The measurements are most compatible with a relative temperature coefficient cT = σ−1 ∂ Tσ = 0.0031 K−1 at 294 K. The cross section and its uncertainty value were obtained using generalised linear regression with correlated uncertainties. It will serve as a reference for ozone absorption spectra required for the long-term remote sensing of atmospheric ozone in the Huggins bands. The comparison with commonly used absorption cross-section data sets for remote sensing reveals a possible bias of about 2 %. This could partly explain a 4 % discrepancy between UV and IR remote sensing data and indicates that further studies will be required to reach the accuracy goal of 1 % in atmospheric reference spectra.
ISSN:1867-8548
1867-1381
1867-8548
DOI:10.5194/amt-11-1707-2018