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22 Junio, 2017

The role of climatic aerosols

Coordinated by the National Observatory of Athens in Greece.
Funded under FP7-PEOPLE.
http://cordis.europa.eu/result/rcn/155894 research*eu results magazine N°41 / April 2015 37
Source: research eu. No. 41. April, 2015.
An EU study has worked to determine the role of atmospheric aerosols in climate processes. Satellite data show the distribution of atmospheric particle sizes, facilitating constant monitoring, the issuing of warnings and better understanding of the dynamics at play.

Aerosols are small particles suspended in the air, and can be of either natural or man-made origin. They play a significant role in climate change, however the exact extent is unknown.

The issue is an international research priority, with the EU funding the two-year AEROMAP (Global mapping of aerosol properties using neural network inversions of ground and satellite based data) project to investigate it. The key question was how aerosol quantities and compositions vary around the globe and over time, which the project addressed using daily whole-Earth satellite maps.

The goal was to subdivide the globe into distinct aerosol types, and to show the distribution of particle sizes in the atmosphere.

Additionally, the project tested the feasibility of conducting global real-time aerosol monitoring. The team further considered constructing an air quality index to assess climatic risks and issue alerts regarding aerosol impact. The project wound up in early 2014.

AEROMAP developed and validated new data mining tools, based on cluster analysis and neural networks. The tools convert satellite data into aerosol microphysical properties for various globally distributed aerosol types. The near-daily maps are used to monitor and classify aerosols as they move about the Earth.

Concerning the feasibility studies, AEROMAP determined that the average global distribution of aerosols can be separated into 10 distinct regions, each having a particular composition. Neural network models analysed eight years of daily data for each region. The models were validated in terms of being able to retrieve aerosol microphysics.

Hence, the project produced global maps showing size distributions of atmospheric aerosols, used to monitor the evolution of atmospheric events. It was not previously possible to observe the evolution of such events, especially over large uninhabited areas such as deserts or oceans. The study also created the first near-daily maps of global air quality produced from aerosol microphysics rather than chemistry. The team developed two indices showing the potential impact on health and visibility.

The research resulted in two conference presentations and four journal papers.

AEROMAP provided a new understanding of the dynamics of atmospheric aerosols, an important factor in climate change. The project enabled the use of satellite data to create almost-daily whole-Earth maps of aerosol properties and their effects.