Airborne measurements of new particle formation in the free troposphere above the Mediterranean Sea during the HYMEX campaign

Abstract

Abstract. While atmospheric new particle formation (NPF) has been observed in various environments and was found to contribute significantly to the total aerosol particle concentration, the production of new particles over open seas is poorly documented in the literature. Nucleation events were detected and analysed over the Mediterranean Sea using two condensation particle counters and a Scanning Mobility Particle Sizer on-board the ATR-42 research aircraft during flights conducted between the 11 September and the 4 November 2012 in the framework of the HYMEX (HYdrological cycle in Mediterranean EXperiment) project. The main purpose of the present work was to characterize the spatial extent of the NPF process. Our findings show that nucleation is occurring over large areas above the Mediterranean Sea in all air mass types. Maximum concentrations of particles in the size range 5–10 nm (N5–10) do not systematically coincide with lower fetches (time spent by the air mass over the sea before sampling), and significant N5–10 values are found for fetches between 0 and 60 h depending on the air mass type. These observations suggest that nucleation events could be more influenced by processes occurring above the sea, rather than linked to synoptic history. The analysis of the vertical extent of nucleation demonstrates that the process is favoured at high altitude, above 1000 m, i.e. frequently in the free troposphere, and more especially between 2000 and 3000 m, where the nucleation frequency is close to 50%. This vertical distribution of nucleation is favoured by the gradients of several parameters, such as the condensation sink, the temperature and the relative humidity. The mixing of two air parcels could also explain the occurrence of nucleation at preferential altitudes. After they formed, particles slowly grow at high altitude to diameters of at least 30 nm while being poorly depleted by coagulation processes. Our analysis of the particle size distributions suggests that particle growth could decrease with increasing altitudes.