DeLiAn - a growing collection of depolarization ratio, lidar ratio and Ångstrom exponent for different aerosol types and mixtures from ground-based lidar observations
Floutsi, Athena Augusta
Leibniz Association
Baars, Holger
Leibniz Association
Engelmann, Ronny
Leibniz Association
Althausen, Dietrich
Leibniz Association
Ansmann, Albert
Leibniz Association
Bohlmann, Stephanie
Leibniz Association
Heese, Birgit
Leibniz Association
Hofer, Julian
Leibniz Association
Kanitz, Thomas
Leibniz Association
Haarig, Moritz
Leibniz Association
Ohneiser, Kevin
Leibniz Association
Radenz, Martin
Leibniz Association
Seifert, Patric
Leibniz Association
Skupin, Annett
Leibniz Association
Yin, Zhenping
Leibniz Association
Abdullaev, Sabur F.
Academy of Sciences of Republic of Tajikistan
Komppula, Mika
Finnish Meteorological Institute
Filioglou, Maria
Finnish Meteorological Institute
Giannakaki, Elina
Finnish Meteorological Institute
Stachlewska, Iwona S.
University of Warsaw
Janicka, Lucja
University of Warsaw
Bortoli, Daniele
University of Evora
Marinou, Eleni
National Observatory of Athens
Amiridis, Vassilis
National Observatory of Athens
Gialitaki, Anna
National Observatory of Athens
Mamouri, Rodanthi-Elisavet
ERATOSTHENES Ctr Excellence
Wandinger, Ulla
Leibniz Association
Journal
Atmospheric Measurement Techniques
ISSN
1867-1381
1867-8548
Open Access
gold
Volume
16
Start page
2353
End page
2379
This paper presents a collection of lidar-derived aerosol intensive optical properties for several aerosol types, namely the particle linear depolarization ratio, the extinction-to-backscatter ratio (lidar ratio) and the angstrom ngstrom exponent. The data collection, named DeLiAn, is based on globally distributed, long-term, ground-based, multiwavelength, Raman and polarization lidar measurements, conducted mainly with lidars that have been developed at the Leibniz Institute for Tropospheric Research. The intensive optical properties are presented at two wavelengths, 355 and 532 nm, for 13 aerosol categories. The categories cover the basic aerosol types (i.e., marine, pollution, continental European background, volcanic ash, smoke, mineral dust), as well as the most frequently observed mixtures they form. This extensive collection also incorporates more peculiar aerosol categories, including dried marine aerosol that, compared to marine aerosol, exhibits a significantly enhanced depolarization ratio (up to 15 %). Besides Saharan dust, additional mineral dust types related to their source region were identified due to their lower lidar ratios (Central Asian and Middle Eastern dust). In addition, extreme wildfire events (such as in north America and Australia) emitted smoke into the stratosphere showing significantly different optical properties, i.e., high depolarization values (up to 25 %), compared to tropospheric smoke. The data collection reflects and underlines the variety of aerosol mixtures in the atmosphere and can be used for the development of aerosol-typing schemes. The paper contains the most up-to-date and comprehensive overview of optical properties from aerosol lidar measurements and, therefore, provides a solid basis for future aerosol retrievals in the frame of both spaceborne and ground-based lidars. Furthermore, DeLiAn can assist the efforts for the harmonization of satellite records of aerosol properties performed at different wavelengths.