MAX‐DOAS O 4 measurements: A new technique to derive information on atmospheric aerosols—Principles and information content

MAX‐DOAS O 4 measurements: A new technique to derive information on atmospheric aerosols—Principles and information content

Multi AXis Differential Optical Absorption Spectroscopy (MAX‐DOAS) observations of the oxygen dimer O 4 which can serve as a new method for the determination of atmospheric aerosol properties are presented. Like established methods, e.g., Sun radiometer and LIDAR measurements, MAX‐DOAS O 4 observati...

Full description

Saved in:
Bibliographic Details
Published in:Journal of Geophysical Research: Atmospheres Vol. 109; no. D22
Main Authors: Wagner, T., Dix, B., Friedeburg, C. v., Frieß, U., Sanghavi, S., Sinreich, R., Platt, U.
Format: Journal Article
Language:English
Published: 27-11-2004
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Multi AXis Differential Optical Absorption Spectroscopy (MAX‐DOAS) observations of the oxygen dimer O 4 which can serve as a new method for the determination of atmospheric aerosol properties are presented. Like established methods, e.g., Sun radiometer and LIDAR measurements, MAX‐DOAS O 4 observations determine optical properties of aerosol under atmospheric conditions (not dried). However, the novel technique has two major advantages: It utilizes differential O 4 absorption structures and thus does not require absolute radiometric calibration. In addition, O 4 observations using this method provide a new kind of information: since the atmospheric O 4 profile depends strongly on altitude, they can yield information on the atmospheric light path distribution and in particular on the atmospheric aerosol profile. From O 4 observations during clear days and from atmospheric radiative transfer modeling, we conclude that our new method is especially sensitive to the aerosol extinction close to the ground. In addition, O 4 observations using this method yield information on the penetration depth of the incident direct solar radiation. O 4 observations at different azimuth angles can also provide information on the aerosol scattering phase function. We found that MAX‐DOAS O 4 observations are a very sensitive method: even aerosol extinction below 0.001 could be detected. In addition to the O 4 absorptions we also investigated the magnitude of the Ring effect and the (relative) intensity. Both quantities yield valuable further information on atmospheric aerosols. From the simultaneous analysis of the observed O 4 absorption and the measured intensity, in particular, information on the absorbing properties of the aerosols might be derived. The aerosol information derived from MAX‐DOAS observations can be used for the quantitative analysis of various trace gases also analyzed from the measured spectra.
ISSN:0148-0227
DOI:10.1029/2004JD004904