Geoscientific Model Development (Jun 2017)

An emission module for ICON-ART 2.0: implementation and simulations of acetone

  • M. Weimer,
  • M. Weimer,
  • J. Schröter,
  • J. Eckstein,
  • K. Deetz,
  • M. Neumaier,
  • G. Fischbeck,
  • L. Hu,
  • D. B. Millet,
  • D. Rieger,
  • H. Vogel,
  • B. Vogel,
  • T. Reddmann,
  • O. Kirner,
  • R. Ruhnke,
  • P. Braesicke

DOI
https://doi.org/10.5194/gmd-10-2471-2017
Journal volume & issue
Vol. 10
pp. 2471 – 2494

Abstract

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We present a recently developed emission module for the ICON (ICOsahedral Non-hydrostatic)-ART (Aerosols and Reactive Trace gases) modelling framework. The emission module processes external flux data sets and increments the tracer volume mixing ratios in the boundary layer accordingly. The performance of the emission module is illustrated with simulations of acetone, using a simplified chemical depletion mechanism based on a reaction with OH and photolysis only. In our model setup, we calculate a tropospheric acetone lifetime of 33 days, which is in good agreement with the literature. We compare our results with ground-based as well as with airborne IAGOS-CARIBIC measurements in the upper troposphere and lowermost stratosphere (UTLS) in terms of phase and amplitude of the annual cycle. In all our ICON-ART simulations the general seasonal variability is well represented but uncertainties remain concerning the magnitude of the acetone mixing ratio in the UTLS region. In addition, the module for online calculations of biogenic emissions (MEGAN2.1) is implemented in ICON-ART and can replace the offline biogenic emission data sets. In a sensitivity study we show how different parametrisations of the leaf area index (LAI) change the emission fluxes calculated by MEGAN2.1 and demonstrate the importance of an adequate treatment of the LAI within MEGAN2.1. We conclude that the emission module performs well with offline and online emission fluxes and allows the simulation of the annual cycles of emissions-dominated substances.