Abstract
Abstract. MIPAS (Michelson Interferometer for Passive Atmospheric Sounding) is a mid-infrared limb emission sounder that operated on board the polar satellite ENVISAT from 2002 to 2012. The retrieval algorithm used by the European Space Agency to process MIPAS measurements exploits the assumption that the atmosphere is horizontally homogeneous. However, previous studies highlighted how this assumption causes significant errors on the retrieved profiles of some MIPAS target species.In this paper we quantify the errors induced by this assumption and evaluate the performances of three different algorithms that can be used to mitigate the problem. We generate synthetic observations with a high spatial resolution atmospheric model and carry out the retrievals with four alternative methods. The first assumes horizontal homogeneity (1-D retrieval), the second includes a model of the horizontal gradient of atmospheric temperature (1-D plus temperature gradient retrieval), the third accounts for an horizontal gradient of temperature and composition (1-D plus temperature and composition gradient retrieval), while the fourth is the full two-dimensional (2-D) inversion approach.Our results highlight that the 1-D retrieval implies errors that are significant for averages of profiles. Furthermore, for some targets (e.g. T, CH4 and N2O below 10 hPa) the error induced by the 1-D approximation also becomes visible in the individual retrieved profiles. The inclusion of any kind of horizontal variability model improves all the targets with respect to the horizontal homogeneity assumption. For temperature, HNO3 and CFC-11, the inclusion of an horizontal temperature gradient leads to a significant reduction of the error. For other targets, such as H2O, O3, N2O, CH4, the improvements due to the inclusion of an horizontal temperature gradient are minor. In these cases, the inclusion of a gradient in the target volume mixing ratio leads to significant improvements. Among all the methods tested in this work, the 2-D approach, as expected, implies the smallest errors for almost all the target parameters. This residual error of the 2-D approach is the smoothing caused by the retrieval grid, which is coarser than that of the atmospheric model.
Highlights
Satellite limb scanning spectrometers have been widely used to measure atmospheric composition and its evolution with time
In the same figures we show the values of AX– DX differences calculated from the ESA IPF V6.0 Level 2 MIPAS data of December 2005 to 2010
For example (a) we use simulated instead of real data, (b) we consider different years and months and (c) we use horizontal gradients obtained from a previous 1-D retrieval while Kiefer et al (2010) uses gradients obtained from European Centre for Medium-range Weather Forecasts (ECMWF) re-analysis
Summary
Satellite limb scanning spectrometers have been widely used to measure atmospheric composition and its evolution with time. The instrument observed the atmospheric midinfrared emission spectrum using the limb-scanning observation technique (Fischer et al, 2008) In this spectral region several minor atmospheric constituents are active, and from the inversion of the spectrum it is possible to determine their volume mixing ratio (VMR) vertical profile in the height range from 6 to 70 km. Similar horizontal gradients of temperature or composition are sounded by the instrument line of sight with the opposite sign in the ascending and the descending parts of the orbit. This sign difference causes opposite systematic errors in the profiles retrieved from the measurements acquired in the ascending and descending parts of the orbits
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