Atmosphere (Nov 2018)

Advanced Ultraviolet Radiation and Ozone Retrieval for Applications (AURORA): A Project Overview

  • Ugo Cortesi,
  • Simone Ceccherini,
  • Samuele Del Bianco,
  • Marco Gai,
  • Cecilia Tirelli,
  • Nicola Zoppetti,
  • Flavio Barbara,
  • Marc Bonazountas,
  • Argyros Argyridis,
  • André Bós,
  • Edo Loenen,
  • Antti Arola,
  • Jukka Kujanpää,
  • Antti Lipponen,
  • William Wandji Nyamsi,
  • Ronald van der A,
  • Jacob van Peet,
  • Olaf Tuinder,
  • Vincenzo Farruggia,
  • Andrea Masini,
  • Emilio Simeone,
  • Rossana Dragani,
  • Arno Keppens,
  • Jean-Christopher Lambert,
  • Michel van Roozendael,
  • Christophe Lerot,
  • Huan Yu,
  • Koen Verberne

DOI
https://doi.org/10.3390/atmos9110454
Journal volume & issue
Vol. 9, no. 11
p. 454

Abstract

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With the launch of the Sentinel-5 Precursor (S-5P, lifted-off on 13 October 2017), Sentinel-4 (S-4) and Sentinel-5 (S-5)(from 2021 and 2023 onwards, respectively) operational missions of the ESA/EU Copernicus program, a massive amount of atmospheric composition data with unprecedented quality will become available from geostationary (GEO) and low Earth orbit (LEO) observations. Enhanced observational capabilities are expected to foster deeper insight than ever before on key issues relevant for air quality, stratospheric ozone, solar radiation, and climate. A major potential strength of the Sentinel observations lies in the exploitation of complementary information that originates from simultaneous and independent satellite measurements of the same air mass. The core purpose of the AURORA (Advanced Ultraviolet Radiation and Ozone Retrieval for Applications) project is to investigate this exploitation from a novel approach for merging data acquired in different spectral regions from on board the GEO and LEO platforms. A data processing chain is implemented and tested on synthetic observations. A new data algorithm combines the ultraviolet, visible and thermal infrared ozone products into S-4 and S-5(P) fused profiles. These fused products are then ingested into state-of-the-art data assimilation systems to obtain a unique ozone profile in analyses and forecasts mode. A comparative evaluation and validation of fused products assimilation versus the assimilation of the operational products will seek to demonstrate the improvements achieved by the proposed approach. This contribution provides a first general overview of the project, and discusses both the challenges of developing a technological infrastructure for implementing the AURORA concept, and the potential for applications of AURORA derived products, such as tropospheric ozone and UV surface radiation, in sectors such as air quality monitoring and health.

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