A Climatological Satellite Assessment of Absorbing Carbonaceous Aerosols on a Global Scale

Hatzianastassiou,; Kalaitzi, Stavroula; Gavrouzou,; Gkikas,; Korras-Carraca, Marios-Bruno; Mihalopoulos,

doi:10.3390/atmos10110671

Cited by 3 publications

(2 citation statements)

References 134 publications

(180 reference statements)

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“…A remarkable feature in Figure 4 is the presence of DA in the southeastern Atlantic Ocean, off the coasts of Angola, in up to 3-16 days/month during the period from July to September, maximized in August (up to 19 days/month). This appearance of DA is observed over the same location, where absorbing carbonaceous aerosols (ACA) are observed and detected by a companion version of the present algorithm [99] using the same satellite data (MODIS and OMI). These ACA are associated with an effective westward transport of African biomass aerosols originating from extensive agricultural burning and wildfires over Angola and Congo [99].…”

Section: Geographical Distributionsupporting

confidence: 64%

“…This appearance of DA is observed over the same location, where absorbing carbonaceous aerosols (ACA) are observed and detected by a companion version of the present algorithm [99] using the same satellite data (MODIS and OMI). These ACA are associated with an effective westward transport of African biomass aerosols originating from extensive agricultural burning and wildfires over Angola and Congo [99]. These ACA aerosols are convectively uplifted to the free troposphere and subsequently transported westward (e.g., up to the Ascension Island 2000 km offshore continental Africa) by a well-established anticyclonic circulation induced by the semi-permanent sub-tropical anticyclone of the South Atlantic [100].…”

Section: Geographical Distributionsupporting

confidence: 64%

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A Global Climatology of Dust Aerosols Based on Satellite Data: Spatial, Seasonal and Inter-Annual Patterns over the Period 2005–2019

et al. 2021

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A satellite-based algorithm is developed and used to determine the presence of dust aerosols on a global scale. The algorithm uses as input aerosol optical properties from the MOderate Resolution Imaging Spectroradiometer (MODIS)-Aqua Collection 6.1 and Ozone Monitoring Instrument (OMI)-Aura version v003 (OMAER-UV) datasets and identifies the existence of dust aerosols in the atmosphere by applying specific thresholds, which ensure the coarse size and the absorptivity of dust aerosols, on the input optical properties. The utilized aerosol optical properties are the multiwavelength aerosol optical depth (AOD), the Aerosol Absorption Index (AI) and the Ångström Exponent (a). The algorithm operates on a daily basis and at 1° × 1° latitude-longitude spatial resolution for the period 2005–2019 and computes the absolute and relative frequency of the occurrence of dust. The monthly and annual mean frequencies are calculated on a pixel level for each year of the study period, enabling the study of the seasonal as well as the inter-annual variation of dust aerosols’ occurrence all over the globe. Temporal averaging is also applied to the annual values in order to estimate the 15-year climatological mean values. Apart from temporal, a spatial averaging is also applied for the entire globe as well as for specific regions of interest, namely great global deserts and areas of desert dust export. According to the algorithm results, the highest frequencies of dust occurrence (up to 160 days/year) are primarily observed over the western part of North Africa (Sahara), and over the broader area of Bodélé, and secondarily over the Asian Taklamakan desert (140 days/year). For most of the study regions, the maximum frequencies appear in boreal spring and/or summer and the minimum ones in winter or autumn. A clear seasonality of global dust is revealed, with the lowest frequencies in November–December and the highest ones in June. Finally, an increasing trend of global dust frequency of occurrence from 2005 to 2019, equal to 56.2%, is also found. Such an increasing trend is observed over all study regions except for North Middle East, where a slight decreasing trend (−2.4%) is found.

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Section: Geographical Distributionsupporting

confidence: 64%

Section: Geographical Distributionsupporting

confidence: 64%

A Global Climatology of Dust Aerosols Based on Satellite Data: Spatial, Seasonal and Inter-Annual Patterns over the Period 2005–2019

et al. 2021

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A comparison of atmospheric aerosol absorption properties from the MERRA-2 reanalysis with AERONET

Bakatsoula

Korras-Carraca

Hatzianastassiou

et al. 2023

Atmospheric Environment

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Global Clear-Sky Aerosol Speciated Direct Radiative Effects over 40 Years (1980–2019)

et al. 2021

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We assess the 40-year climatological clear-sky global direct radiative effect (DRE) of five main aerosol types using the MERRA-2 reanalysis and a spectral radiative transfer model (FORTH). The study takes advantage of aerosol-speciated, spectrally and vertically resolved optical properties over the period 1980–2019, to accurately determine the aerosol DREs, emphasizing the attribution of the total DREs to each aerosol type. The results show that aerosols radiatively cool the Earth’s surface and heat its atmosphere by 7.56 and 2.35 Wm−2, respectively, overall cooling the planet by 5.21 Wm−2, partly counterbalancing the anthropogenic greenhouse global warming during 1980–2019. These DRE values differ significantly in terms of magnitude, and even sign, among the aerosol types (sulfate and black carbon aerosols cool and heat the planet by 1.88 and 0.19 Wm−2, respectively), the hemispheres (larger NH than SH values), the surface cover type (larger land than ocean values) or the seasons (larger values in local spring and summer), while considerable inter-decadal changes are evident. These DRE differences are even larger by up to an order of magnitude on a regional scale, highlighting the important role of the aerosol direct radiative effect for local and global climate.

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A Climatological Satellite Assessment of Absorbing Carbonaceous Aerosols on a Global Scale

Cited by 3 publications

References 134 publications

A Global Climatology of Dust Aerosols Based on Satellite Data: Spatial, Seasonal and Inter-Annual Patterns over the Period 2005–2019

A Global Climatology of Dust Aerosols Based on Satellite Data: Spatial, Seasonal and Inter-Annual Patterns over the Period 2005–2019

A comparison of atmospheric aerosol absorption properties from the MERRA-2 reanalysis with AERONET

Global Clear-Sky Aerosol Speciated Direct Radiative Effects over 40 Years (1980–2019)

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