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Sensitivity of simulated rain intensity and kinetic energy to aerosols and warm‐rain microphysics during the extreme event of July 2021 in Belgium

Kwinten Van Weverberg (UGent) , N. Ghilain, E. Goudenhoofdt, Matthias Barbier, Ester Koistinen, S. Doutreloup, Bert Van Schaeybroeck (UGent) , Amaury Frankl (UGent) and P. Field
(2024) QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY. 150(763). p.3322-3345
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Abstract
This article presents an evaluation and sensitivity analysis of km-scale simulations of an unprecedented extreme rainfall event over Europe, with a specific focus on sub-hourly extremes, size distributions, and kinetic energy (KE) of rain. These variables are critical for hydrological applications, such as flood forecasting or soil-loss monitoring, but are rarely directly obtained from numerical weather prediction (NWP) models. The simulations presented here reproduce the overall characteristics of the event, but overestimate the extreme rain rates. The rain rate-KE relation was well-captured, despite too large volume-mean drop diameters. Amongst the sensitivities investigated, the representation of the raindrop self-collection-breakup equilibrium and the raindrop size-distribution shape were found to have the most profound impact on the rainfall characteristics. While extreme rain rates varied within 30%, the rain KE varied by a factor of four between the realistic perturbations to the microphysical assumptions. Changes to the aerosol concentration and rain terminal velocity relations were found to have a relatively smaller impact. Given the large uncertainties, a continued effort to improve the model physics will be indispensable to estimate rain intensities and KE reliably for direct hydrological applications. Short-range rainfall extremes, raindrop size distributions and rain kinetic energy are rarely directly obtained from Numerical Weather Prediction models. We present simulations of the July 2021 extreme rainfall event over Western Europe and show that these variables are fairly well reproduced by the model, but are also very sensitive to uncertainties in particularly the parametrisation of raindrop breakup and the raindrop size distribution shape. Aerosol concentration was found to have limited impact on these variables. image
Keywords
extreme precipitation, microphysics parametrization, numerical weather prediction, rain kinetic energy, BULK MICROPHYSICS, SIZE DISTRIBUTION, UNIFIED MODEL, DROP SIZE, CONVECTIVE CLOUDS, FLOOD EVENT, PART 1, PARAMETERIZATION, PRECIPITATION, EROSIVITY

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MLA
Van Weverberg, Kwinten, et al. “Sensitivity of Simulated Rain Intensity and Kinetic Energy to Aerosols and Warm‐rain Microphysics during the Extreme Event of July 2021 in Belgium.” QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY, vol. 150, no. 763, 2024, pp. 3322–45, doi:10.1002/qj.4761.
APA
Van Weverberg, K., Ghilain, N., Goudenhoofdt, E., Barbier, M., Koistinen, E., Doutreloup, S., … Field, P. (2024). Sensitivity of simulated rain intensity and kinetic energy to aerosols and warm‐rain microphysics during the extreme event of July 2021 in Belgium. QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY, 150(763), 3322–3345. https://doi.org/10.1002/qj.4761
Chicago author-date
Van Weverberg, Kwinten, N. Ghilain, E. Goudenhoofdt, Matthias Barbier, Ester Koistinen, S. Doutreloup, Bert Van Schaeybroeck, Amaury Frankl, and P. Field. 2024. “Sensitivity of Simulated Rain Intensity and Kinetic Energy to Aerosols and Warm‐rain Microphysics during the Extreme Event of July 2021 in Belgium.” QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY 150 (763): 3322–45. https://doi.org/10.1002/qj.4761.
Chicago author-date (all authors)
Van Weverberg, Kwinten, N. Ghilain, E. Goudenhoofdt, Matthias Barbier, Ester Koistinen, S. Doutreloup, Bert Van Schaeybroeck, Amaury Frankl, and P. Field. 2024. “Sensitivity of Simulated Rain Intensity and Kinetic Energy to Aerosols and Warm‐rain Microphysics during the Extreme Event of July 2021 in Belgium.” QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY 150 (763): 3322–3345. doi:10.1002/qj.4761.
Vancouver
1.
Van Weverberg K, Ghilain N, Goudenhoofdt E, Barbier M, Koistinen E, Doutreloup S, et al. Sensitivity of simulated rain intensity and kinetic energy to aerosols and warm‐rain microphysics during the extreme event of July 2021 in Belgium. QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY. 2024;150(763):3322–45.
IEEE
[1]
K. Van Weverberg et al., “Sensitivity of simulated rain intensity and kinetic energy to aerosols and warm‐rain microphysics during the extreme event of July 2021 in Belgium,” QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY, vol. 150, no. 763, pp. 3322–3345, 2024.
@article{01HYYX5MXKVQGD886B9DSX1VHF,
  abstract     = {{This article presents an evaluation and sensitivity analysis of km-scale simulations of an unprecedented extreme rainfall event over Europe, with a specific focus on sub-hourly extremes, size distributions, and kinetic energy (KE) of rain. These variables are critical for hydrological applications, such as flood forecasting or soil-loss monitoring, but are rarely directly obtained from numerical weather prediction (NWP) models. The simulations presented here reproduce the overall characteristics of the event, but overestimate the extreme rain rates. The rain rate-KE relation was well-captured, despite too large volume-mean drop diameters. Amongst the sensitivities investigated, the representation of the raindrop self-collection-breakup equilibrium and the raindrop size-distribution shape were found to have the most profound impact on the rainfall characteristics. While extreme rain rates varied within 30%, the rain KE varied by a factor of four between the realistic perturbations to the microphysical assumptions. Changes to the aerosol concentration and rain terminal velocity relations were found to have a relatively smaller impact. Given the large uncertainties, a continued effort to improve the model physics will be indispensable to estimate rain intensities and KE reliably for direct hydrological applications.

Short-range rainfall extremes, raindrop size distributions and rain kinetic energy are rarely directly obtained from Numerical Weather Prediction models. We present simulations of the July 2021 extreme rainfall event over Western Europe and show that these variables are fairly well reproduced by the model, but are also very sensitive to uncertainties in particularly the parametrisation of raindrop breakup and the raindrop size distribution shape. Aerosol concentration was found to have limited impact on these variables. image}},
  author       = {{Van Weverberg, Kwinten and Ghilain, N. and Goudenhoofdt, E. and Barbier, Matthias and Koistinen, Ester and Doutreloup, S. and Van Schaeybroeck, Bert and Frankl, Amaury and Field, P.}},
  issn         = {{0035-9009}},
  journal      = {{QUARTERLY JOURNAL OF THE ROYAL METEOROLOGICAL SOCIETY}},
  keywords     = {{extreme precipitation,microphysics parametrization,numerical weather prediction,rain kinetic energy,BULK MICROPHYSICS,SIZE DISTRIBUTION,UNIFIED MODEL,DROP SIZE,CONVECTIVE CLOUDS,FLOOD EVENT,PART 1,PARAMETERIZATION,PRECIPITATION,EROSIVITY}},
  language     = {{eng}},
  number       = {{763}},
  pages        = {{3322--3345}},
  title        = {{Sensitivity of simulated rain intensity and kinetic energy to aerosols and warm‐rain microphysics during the extreme event of July 2021 in Belgium}},
  url          = {{http://doi.org/10.1002/qj.4761}},
  volume       = {{150}},
  year         = {{2024}},
}
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