Emmanuel Porcheron scite author profile

Abstract. In the case of severe accident with loss of containment in a nuclear plant, radionuclides are released into the atmosphere in the form of both gases and aerosol particles (Baklanov and Sørensen, 2001). The analysis of radioactive aerosol scavenged by rain after the Chernobyl accident highlights certain differences between the modelling studies and the environmental measurements. Part of these discrepancies can probably be attributed to uncertainties in the efficiencies used to calculate aerosol particle collection by raindrops, particularly drops with a diameter larger than one millimetre. In order to address the issue of these uncertainties, an experimental study was performed to close the gaps still existing for this key microphysical parameter. In this paper, attention is first focused on the efficiency with which aerosol particles in the accumulation mode are collected by raindrops with a diameter of 2 mm. The collection efficiencies measured for aerosol particle in the sub-micron range are quantitatively consistent with previous theoretical model developed by Beard (1974) and thus highlight the major role of rear capture in the submicron range.

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The importance of new collection efficiency values including the effect of rear capture for the below-cloud scavenging of aerosol particles

Quérel

Monier

Flossmann

et al. 2014

Atmospheric Research

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Real-time global interferometric laser imaging for the droplet sizing (ILIDS) algorithm for airborne research

Quérel¹,

Lemaître²,

Brunel³

et al. 2009

Meas. Sci. Technol.

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Our objective was to develop an airborne optical sizemeter for atmospheric water droplet characterization. We chose the ILIDS (interferometric laser imaging for droplet sizing) method. This paper details the acquisition method developed to implement the image processing and the experimental tests performed to validate the method. The purpose is to develop a strategy for real-time data analysis in order to obtain information on droplets size during flight; this work is included in the EUFAR project that is supported by the 7th Framework Program of the European Commission (FP7).

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Experimental evidence of the rear capture of aerosol particles by raindrops

Lemaître

Quérel

Monier³

et al. 2017

Atmos. Chem. Phys.

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Abstract. This article presents new measurements of the efficiency with which aerosol particles of accumulation mode size are collected by a 1.25 mm sized raindrop. These laboratory measurements provide the link to reconcile the scavenging coefficients obtained from theoretical approaches with those from experimental studies. We provide here experimental proof of the rear capture mechanism in the flow around drops, which has a fundamental effect on submicroscopic particles. These experiments thus confirm the efficiencies theoretically simulated by Beard (1974). Finally, we propose a semi-analytical expression to take into account this essential mechanism to calculate the collection efficiency for drops within the rain size range.

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The TONUS CFD code for hydrogen risk analysis: Physical models, numerical schemes and validation matrix

Kudriakov

Dabbene

Studer

et al. 2008

Nuclear Engineering and Design

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