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by Taufour, M., Vié, B., Augros, C., Boudevillain, B., Delanoë, J., Delautier, G., Ducrocq, V., Lac, C., Pinty, J.-P. and Schwarzenböck, A.
Abstract:
The goal of this paper is to present and evaluate the new LIMA (Liquid Ice Multiple Aerosols) microphysical scheme, which predicts six water species (water vapour, cloud water, rainwater, primary ice crystals, snow aggregates, and graupel). LIMA uses a two-moment parametrization for three hydrometeor species (ice crystals, cloud droplets, and raindrops), and is derived from the one-moment scheme ICE3 used daily in the AROME cloud-resolving operational model at Météo-France. In addition, it integrates a prognostic representation of the aerosol population. To evaluate the scheme, we simulate two well-documented Heavy Precipitation Events from the HyMeX (Hydrological cycle in the Mediterranean Experiment) campaign. The LIMA simulations are compared to ICE3 simulations and to a large variety of observations, such as rainfall accumulation from rain gauges, particle size distributions from disdrometers, airborne in situ measurements of ice particles, and dual-polarization radar variables. The evaluation suggests that the rain mixing ratio prognosed by LIMA is more realistic than that prognosed by ICE3. Comparisons with disdrometers and dual-polarization radars highlight the better representation of the rain microphysical variability when using LIMA and also its overprediction of raindrops with large diameters. The vertical composition of the convective cells is also improved by the two-moment ice parametrization in the LIMA scheme, which impacts the contents of the one-moment parametrized snow and graupel species. This evaluation of LIMA suggests ways to improve the hydrometeor representation, focusing especially on the description of the particle size distributions for different water species.
Reference:
Taufour, M., Vié, B., Augros, C., Boudevillain, B., Delanoë, J., Delautier, G., Ducrocq, V., Lac, C., Pinty, J.-P. and Schwarzenböck, A., 2018: Evaluation of the two-moment scheme LIMA based on microphysical observations from the HyMeX campaignQuarterly Journal of the Royal Meteorological Society, 144, 1398-1414.
Bibtex Entry:
@Article{Taufour2018,
  author        = {Taufour, M. and Vié, B. and Augros, C. and Boudevillain, B. and Delanoë, J. and Delautier, G. and Ducrocq, V. and Lac, C. and Pinty, J.-P. and Schwarzenböck, A.},
  title         = {Evaluation of the two-moment scheme LIMA based on microphysical observations from the HyMeX campaign},
  journal       = {Quarterly Journal of the Royal Meteorological Society},
  year          = {2018},
  volume        = {144},
  number        = {714},
  pages         = {1398-1414},
  abstract      = {The goal of this paper is to present and evaluate the new LIMA (Liquid Ice Multiple Aerosols) microphysical scheme, which predicts six water species (water vapour, cloud water, rainwater, primary ice crystals, snow aggregates, and graupel). LIMA uses a two-moment parametrization for three hydrometeor species (ice crystals, cloud droplets, and raindrops), and is derived from the one-moment scheme ICE3 used daily in the AROME cloud-resolving operational model at Météo-France. In addition, it integrates a prognostic representation of the aerosol population. To evaluate the scheme, we simulate two well-documented Heavy Precipitation Events from the HyMeX (Hydrological cycle in the Mediterranean Experiment) campaign. The LIMA simulations are compared to ICE3 simulations and to a large variety of observations, such as rainfall accumulation from rain gauges, particle size distributions from disdrometers, airborne in situ measurements of ice particles, and dual-polarization radar variables. The evaluation suggests that the rain mixing ratio prognosed by LIMA is more realistic than that prognosed by ICE3. Comparisons with disdrometers and dual-polarization radars highlight the better representation of the rain microphysical variability when using LIMA and also its overprediction of raindrops with large diameters. The vertical composition of the convective cells is also improved by the two-moment ice parametrization in the LIMA scheme, which impacts the contents of the one-moment parametrized snow and graupel species. This evaluation of LIMA suggests ways to improve the hydrometeor representation, focusing especially on the description of the particle size distributions for different water species.},
  copublication = {10: 10 Fr},
  doi           = {10.1002/qj.3283},
  eprint        = {https://rmets.onlinelibrary.wiley.com/doi/pdf/10.1002/qj.3283},
  keywords      = {HyMeX; mesoscale convective simulations; microphysics; observational data analysis;},
  owner         = {hymexw},
  timestamp     = {2019-01-25},
  url           = {https://rmets.onlinelibrary.wiley.com/doi/abs/10.1002/qj.3283},
}