Abstract

Abstract. During transport by advection, atmospheric nonspherical particles, such as volcanic ash, desert dust or sea-salt particles experience several chemical and physical processes, leading to a complex vertical atmospheric layering at remote sites where intrusion episodes occur. In this paper, a new methodology is proposed to analyse this complex vertical layering in the case of a two/three-component particle external mixtures. This methodology relies on an analysis of the spectral and polarization properties of the light backscattered by atmospheric particles. It is based on combining a sensitive and accurate UV-VIS polarization lidar experiment with T-matrix numerical simulations and air mass back trajectories. The Lyon UV-VIS polarization lidar is used to efficiently partition the particle mixture into its nonspherical components, while the T-matrix method is used for simulating the backscattering and depolarization properties of nonspherical volcanic ash, desert dust and sea-salt particles. It is shown that the particle mixtures' depolarization ratio δ p differs from the nonspherical particles' depolarization ratio δns due to the presence of spherical particles in the mixture. Hence, after identifying a tracer for nonspherical particles, particle backscattering coefficients specific to each nonspherical component can be retrieved in a two-component external mixture. For three-component mixtures, the spectral properties of light must in addition be exploited by using a dual-wavelength polarization lidar. Hence, for the first time, in a three-component external mixture, the nonsphericity of each particle is taken into account in a so-called 2β + 2δ formalism. Applications of this new methodology are then demonstrated in two case studies carried out in Lyon, France, related to the mixing of Eyjafjallajökull volcanic ash with sulfate particles (case of a two-component mixture) and to the mixing of dust with sea-salt and water-soluble particles (case of a three-component mixture). This new methodology, which is able to provide separate vertical profiles of backscattering coefficient for mixed atmospheric dust, sea-salt and water-soluble particles, may be useful for accurate radiative forcing assessments.

Highlights

  • UDsefautlaforSayccsutreatme rsadiative forcing the spectral and polarization properties of the light backscattered by atmospheric particles

  • We have proposed and applied a new methodology to evaluate the partitioning of two- or three-component particle external mixtures of volcanic ash, desert dust, seawww.atmos-chem-phys.net/13/6757/2013/

  • It consists in combining dual-wavelength polarization lidar measurements with light-scattering numerical simulations and air mass back trajectories

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Summary

Introduction

UDsefautlaforSayccsutreatme rsadiative forcing the spectral and polarization properties of the light backscattered by atmospheric particles. For the first time, in a 1995; Winker et al, 2009, 2010; Vernier et al, 2011), and three-component external mixture, the nonsphericity of each remote sensing is a major source of global data on aerosol particle is taken into account in a so-called 2β + 2δ formal- particle distributions, needed in radiative and climate forcism Applications of this new methodology are demon- ing assessments. The Slacokloidf kEnoawrlethdge on volcanic strated in two case studies carried out in Lyon, France, related ash, desert dust and sea-salt particles induces large uncertainties in the Earth’s climate

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