Complex vertical aerosols layering of natural and anthropogenic particles over the southeastern mediterranean: observations with earlinet lidar and aeronet photometer at Lemesos, Cyprus and comparison with transport modeling results
Date Issued
September 17, 2012
Abstract
In the south-eastern Mediterranean, complex aerosol profiles consisting of separate layers of different
natural and anthropogenic particles or aerosol mixtures can be observed frequently. Consequently,
these aerosols can have a complicated influence on climatic conditions, directly as well as indirectly
via cloud processes. Observations of such complex aerosol layering within networks such as the
European Aerosol Research Lidar Network (EARLINET) and the Aerosol Robotic Network
(AERONET) and comparison of these observations with respective aerosol products of regional to
global atmospheric transport modelling are required to improve our understanding of life cycles of
aerosols and aerosol mixtures and their impact on climate. In this work is presented a case study of a
desert dust outbreak from Syria and Saudi Arabia towards the eastern Mediterranean, occurred in
September 2011. The observations were performed with a 532-nm polarization lidar (member of
EARLINET) and a sun sky CIMEL sun-photometer (member of AERONET) operating at 8 channels
from 340 to 1640 nm wavelength at Lemesos District, Cyprus (34°N, 33°E). The dust-laden air
became mixed with air masses that crossed sources rich of biomass burning smoke and anthropogenic
pollution (Ukraine, Russia, and Turkey). Over the Mediterranean Sea and more precisely over Cyprus,
marine air and anthropogenic haze became mixed in the lower part of the plume by sea breeze
circulations. This case study provides an ideal opportunity to demonstrate the potential of combined
lidar-photometer observations to deliver detailed vertically resolved information of the aerosol
characteristics in terms of particle backscatter and extinction coefficients, and the extinction-tobackscatter ratio, separately for the fine mode particle fraction (mostly smoke in the observed lofted
layers) and the coarse mode fraction (mostly dust in the lofted layers), and volume and mass
concentrations for fine and coarse mode particles. The retrieved aerosol profile data sets were
compared with results of FLEXPART and the mineral dust regional BSC-DREAM8b model
simulations. Good consistency of model and observational data were found and will be presented at
the conference.
natural and anthropogenic particles or aerosol mixtures can be observed frequently. Consequently,
these aerosols can have a complicated influence on climatic conditions, directly as well as indirectly
via cloud processes. Observations of such complex aerosol layering within networks such as the
European Aerosol Research Lidar Network (EARLINET) and the Aerosol Robotic Network
(AERONET) and comparison of these observations with respective aerosol products of regional to
global atmospheric transport modelling are required to improve our understanding of life cycles of
aerosols and aerosol mixtures and their impact on climate. In this work is presented a case study of a
desert dust outbreak from Syria and Saudi Arabia towards the eastern Mediterranean, occurred in
September 2011. The observations were performed with a 532-nm polarization lidar (member of
EARLINET) and a sun sky CIMEL sun-photometer (member of AERONET) operating at 8 channels
from 340 to 1640 nm wavelength at Lemesos District, Cyprus (34°N, 33°E). The dust-laden air
became mixed with air masses that crossed sources rich of biomass burning smoke and anthropogenic
pollution (Ukraine, Russia, and Turkey). Over the Mediterranean Sea and more precisely over Cyprus,
marine air and anthropogenic haze became mixed in the lower part of the plume by sea breeze
circulations. This case study provides an ideal opportunity to demonstrate the potential of combined
lidar-photometer observations to deliver detailed vertically resolved information of the aerosol
characteristics in terms of particle backscatter and extinction coefficients, and the extinction-tobackscatter ratio, separately for the fine mode particle fraction (mostly smoke in the observed lofted
layers) and the coarse mode fraction (mostly dust in the lofted layers), and volume and mass
concentrations for fine and coarse mode particles. The retrieved aerosol profile data sets were
compared with results of FLEXPART and the mineral dust regional BSC-DREAM8b model
simulations. Good consistency of model and observational data were found and will be presented at
the conference.