Please use this identifier to cite or link to this item: http://hdl.handle.net/2122/11654
Authors: Sellitto, Pasquale* 
Zanetel, Claudia* 
di Sarra, Alcide* 
Salerno, Giuseppe* 
Tapparo, Andrea* 
Meloni, Daniela* 
Pace, Giandomenico* 
Caltabiano, Tommaso* 
Briole, Pierre* 
Legras, Bernard* 
Title: The impact of Mount Etna sulfur emissions on the atmospheric composition and aerosol properties in the central Mediterranean: A statistical analysis over the period 2000–2013 based on observations and Lagrangian modelling
Journal: Atmospheric Environment 
Series/Report no.: /148 (2017)
Issue Date: 2017
DOI: 10.1016/j.atmosenv.2016.10.032
Subject Classification04.08. Volcanology 
01.01. Atmosphere 
climatology
Abstract: The emission of gases and aerosols due to volcanic activity may impact significantly atmospheric composition, cloud occurrence and properties, and the regional and global climate. While the effects of strong explosive (stratospheric) eruptions are relatively well known, limited information on the impacts of small to moderate volcanic activities, including passive degassing, is available. In this paper, the downwind impact of Mount Etna's sulfur emissions on the central Mediterranean is investigated on a statistical basis over the period 2000e2013 using: (a) daily sulfur dioxide emission rates measured near crater at Mount Etna with ground-based ultraviolet spectrophotometers, (b) Lagrangian trajectories and simulated plume dispersion obtained with the FLEXPART (FLEXible PARTicle dispersion) model, and (c) long-term observations of column SO2 concentration and aerosol Ångstr€om exponent a at Lampedusa (35.5 N, 12.6 E). This statistical analysis has allowed, for the first time, the characterization of decadal impact of Mount Etna's sulfur emissions on the sulfur dioxide and the aerosol microphysical/optical properties in the central Mediterranean. On average, statistically significant higher SO2 concentrations and smaller aerosol sizes are present when air masses from Mount Etna overpass Lampedusa. Despite being upwind of Lampedusa for only 5% of the time, Mount Etna is potentially responsible for up to 40% and 20% of the SO2 and a extreme values (exceedances of a fixed threshold), respectively, at this location. The most important factor determining this perturbation is the prevailing dynamics, while the magnitude of the SO2 emission rates from Mount Etna appears to be likely important only for relatively strong emissions. The observed perturbations to the aerosol size distribution are expected to produce a direct regional radiative effect in this area.
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