An inter-comparison study of the aerosol optical thickness (AOT) at 0.55 μm retrieved using different satellite instruments and algorithms based on the analysis of backscattered solar light is presented for a single scene over central Europe on October 13th, 2005. For the first time comparisons have been performed for as many as six instruments on multiple satellite platforms. Ten different algorithms are briefly discussed and inter-compared. It was found that on the scale of a single pixel there can be large differences in AOT retrieved over land using different retrieval techniques and instruments. However, these differences are not as pronounced for the average AOT over land. For instance, the average AOT at 0.55 μm for the area 7-12E, 49-53N was equal to 0.14 for MISR, NASA MODIS and POLDER algorithms. It is smaller by 0.01 for the ESA MERIS aerosol product and larger by 0.04 for the MERIS BAER algorithm. AOT as derived using AATSR gives on average larger values as compared to all other instruments, while SCIAMACHY retrievals underestimate the aerosol loading. These discrepancies are explained by uncertainties in a priori assumptions used in the different algorithms and differences in the sensor characteristics. Validation against AERONET shows that MERIS provides the most accurate AOT retrievals for this scene.
Precise calculations of the total Rayleigh-scattering optical depth have been performed at 88 wavelengths ranging from 0.20 to 4.00 microm for the six well-known standard atmosphere models by integrating the volume Rayleigh-scattering coefficient along the vertical atmospheric path from sea level to a 120-km height. The coefficient was determined by use of an improved algorithm based on the Ciddor algorithm [Appl. Opt. 35, 1566 (1996)], extended by us over the 0.20-0.23-microm wavelength range to evaluate the moist air refractive index as a function of wavelength, air pressure, temperature, water-vapor partial pressure, and CO2 volume concentration. The King depolarization factor was also defined taking into account the moisture conditions of air. The results indicate that the influence of water vapor on Rayleigh scattering cannot be neglected at tropospheric altitudes: for standard atmospheric conditions represented in terms of the U.S. Standard Atmosphere (1976) model, the relative variations produced by water vapor in the Rayleigh scattering parameters at a 0.50-microm wavelength turn out to be equal to -0.10% in the moist air refractivity at sea level (where the water-vapor partial pressure is equal to approximately 7.8 hPa), -0.04% in the sea-level King factor, -0.24% in the sea-level Rayleigh-scattering cross section, and -0.06% in the Rayleigh-scattering optical depth.
Abstract. Solar-induced fluorescence (SIF) data from satellites are increasingly
used as a proxy for photosynthetic activity by vegetation and as a
constraint on gross primary production. Here we report on improvements
in the algorithm to retrieve mid-morning (09:30 LT) SIF estimates on
the global scale from the GOME-2 sensor on the MetOp-A satellite (GOME-2A)
for the period 2007–2019. Our new SIFTER (Sun-Induced Fluorescence of
Terrestrial Ecosystems Retrieval) v2 algorithm improves over a
previous version by using a narrower spectral window that avoids
strong oxygen absorption and being less sensitive to water vapour
absorption, by constructing stable reference spectra from a 6-year
period (2007–2012) of atmospheric spectra over the Sahara and by
applying a latitude-dependent zero-level adjustment that accounts for
biases in the data product. We generated stable, good-quality SIF
retrievals between January 2007 and June 2013, when GOME-2A
degradation in the near infrared was still limited. After the
narrowing of the GOME-2A swath in July 2013, we characterised the
throughput degradation of the level-1 data in order to derive
reflectance corrections and apply these for the SIF retrievals between
July 2013 and December 2018. SIFTER v2 data compare well with the
independent NASA v2.8 data product. Especially in the evergreen
tropics, SIFTER v2 no longer shows the underestimates against other
satellite products that were seen in SIFTER v1. The new data product
includes uncertainty estimates for individual observations and is
best used for mostly clear-sky scenes and when spectral residuals
remain below a certain spectral autocorrelation threshold. Our results
support the use of SIFTER v2 data being used as an independent
constraint on photosynthetic activity on regional to global scales.
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