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Dual-wavelength linear depolarization ratio of volcanic aerosols: Lidar measurements of the Eyjafjallajökull plume over Maisach, Germany
Abstract The ash plume of the Eyjafjallajökull eruption in April 2010 offered an exceptional opportunity to assess the potential of advanced lidar systems to characterize the volcanic aerosols. Consequently, the plume was continuously observed in the framework of EARLINET. In this paper we focus on the EARLINET-Raman-depolarization-lidar measurements at Maisach near Munich, Germany. From these data sets the lidar ratio S p and the particle linear depolarization ratio δ p at two wavelengths (355 nm and 532 nm) were retrieved. These quantities can be used to characterize volcanic aerosols and to establish criteria for the discrimination from other aerosol types. In the pure volcanic ash plume, observed until noon of 17 April, wavelength independent values of δ p as high as 0.35 < δ p < 0.38, indicating non-spherical particles, were found, and lidar ratios of 50 < S p < 60 sr at 355 nm and 45 < S p < 55 sr at 532 nm. Later, volcanic aerosols were mixed into the boundary layer. This mixture showed in general lower values of δ p as expected from the contribution of boundary layer aerosols. Especially noteworthy is the increase of δ p with wavelength, when volcanic ash was mixed with small spherical particles.
Highlights ► Lidar ratio and depolarization ratio of volcanic ash is measured at two wavelengths. ► Changes of both parameters are investigated for volcanic ash mixtures. ► Pure volcanic ash layer show high wavelength independent depolarization ratio. ► Mixtures show wavelength dependent depolarization ratio under certain circumstances. ► The contribution of volcanic ash in aerosol mixtures is determined.
Dual-wavelength linear depolarization ratio of volcanic aerosols: Lidar measurements of the Eyjafjallajökull plume over Maisach, Germany
Abstract The ash plume of the Eyjafjallajökull eruption in April 2010 offered an exceptional opportunity to assess the potential of advanced lidar systems to characterize the volcanic aerosols. Consequently, the plume was continuously observed in the framework of EARLINET. In this paper we focus on the EARLINET-Raman-depolarization-lidar measurements at Maisach near Munich, Germany. From these data sets the lidar ratio S p and the particle linear depolarization ratio δ p at two wavelengths (355 nm and 532 nm) were retrieved. These quantities can be used to characterize volcanic aerosols and to establish criteria for the discrimination from other aerosol types. In the pure volcanic ash plume, observed until noon of 17 April, wavelength independent values of δ p as high as 0.35 < δ p < 0.38, indicating non-spherical particles, were found, and lidar ratios of 50 < S p < 60 sr at 355 nm and 45 < S p < 55 sr at 532 nm. Later, volcanic aerosols were mixed into the boundary layer. This mixture showed in general lower values of δ p as expected from the contribution of boundary layer aerosols. Especially noteworthy is the increase of δ p with wavelength, when volcanic ash was mixed with small spherical particles.
Highlights ► Lidar ratio and depolarization ratio of volcanic ash is measured at two wavelengths. ► Changes of both parameters are investigated for volcanic ash mixtures. ► Pure volcanic ash layer show high wavelength independent depolarization ratio. ► Mixtures show wavelength dependent depolarization ratio under certain circumstances. ► The contribution of volcanic ash in aerosol mixtures is determined.
Dual-wavelength linear depolarization ratio of volcanic aerosols: Lidar measurements of the Eyjafjallajökull plume over Maisach, Germany
Groß, Silke (author) / Freudenthaler, Volker (author) / Wiegner, Matthias (author) / Gasteiger, Josef (author) / Geiß, Alexander (author) / Schnell, Franziska (author)
Atmospheric Environment ; 48 ; 85-96
2011-06-07
12 pages
Article (Journal)
Electronic Resource
English
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