Resolving Inhomogeneous Cloud Microphysics Through Cloud-Top Observations of Blue Corona Discharges

Dongshuai Li; Alejandro Luque; Eric C. Bruning; Torsten Neubert; Olivier Chanrion; Yanan Zhu; F. J. Gordillo-Vázquez; Nikolai Østgaard

doi:10.1029/2025GL116520

Resolving Inhomogeneous Cloud Microphysics Through Cloud-Top Observations of Blue Corona Discharges

Dongshuai Li (Corresponding author-nrf)
, Alejandro Luque (Corresponding author)
, Eric C. Bruning
, Torsten Neubert
, Olivier Chanrion
, Yanan Zhu
, F. J. Gordillo-Vázquez
, Nikolai Østgaard

Elementary Processes in Gas Discharges

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Understanding cloud-top microphysics is essential for improving weather forecasting and convection monitoring. In this study, we propose a simplified cloud scattering light model to analyze the influence of inhomogeneities in the cloud microphysical properties on the observations of blue corona discharges (BLUEs) from Atmosphere-Space Interactions Monitor. The results show that the depth inferred from the inhomogeneous model is consistently lower than that from the homogeneous model, with the largest difference reaching 2 km. We then present a new approach to inferring inhomogeneous cloud microphysical profiles based on the optical signals from BLUEs using radio-inferred source depths. These profiles match well with Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation lidar measurements and show a transition nearby tropopause with different exponential change rates above and below it. Our study highlights the potential of combining optical and radio observations of BLUEs to rapidly assess cloud microphysics and monitor convective activity.

Originele taal-2	Engels
Artikelnummer	e2025GL116520
Aantal pagina's	12
Tijdschrift	Geophysical Research Letters
Volume	52
Nummer van het tijdschrift	17
DOI's	https://doi.org/10.1029/2025GL116520
Status	Gepubliceerd - 16 sep. 2025

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Publisher Copyright:
© 2025. The Author(s).

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10.1029/2025GL116520

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title = "Resolving Inhomogeneous Cloud Microphysics Through Cloud-Top Observations of Blue Corona Discharges",

abstract = "Understanding cloud-top microphysics is essential for improving weather forecasting and convection monitoring. In this study, we propose a simplified cloud scattering light model to analyze the influence of inhomogeneities in the cloud microphysical properties on the observations of blue corona discharges (BLUEs) from Atmosphere-Space Interactions Monitor. The results show that the depth inferred from the inhomogeneous model is consistently lower than that from the homogeneous model, with the largest difference reaching 2 km. We then present a new approach to inferring inhomogeneous cloud microphysical profiles based on the optical signals from BLUEs using radio-inferred source depths. These profiles match well with Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation lidar measurements and show a transition nearby tropopause with different exponential change rates above and below it. Our study highlights the potential of combining optical and radio observations of BLUEs to rapidly assess cloud microphysics and monitor convective activity.",

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Resolving Inhomogeneous Cloud Microphysics Through Cloud-Top Observations of Blue Corona Discharges. / Li, Dongshuai (Corresponding author-nrf); Luque, Alejandro (Corresponding author); Bruning, Eric C. et al.
In: Geophysical Research Letters, Vol. 52, Nr. 17, e2025GL116520, 16.09.2025.

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

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T1 - Resolving Inhomogeneous Cloud Microphysics Through Cloud-Top Observations of Blue Corona Discharges

AU - Luque, Alejandro

AU - Bruning, Eric C.

AU - Neubert, Torsten

AU - Chanrion, Olivier

AU - Zhu, Yanan

AU - Gordillo-Vázquez, F. J.

AU - Østgaard, Nikolai

A2 - Li, Dongshuai

PY - 2025/9/16

Y1 - 2025/9/16

N2 - Understanding cloud-top microphysics is essential for improving weather forecasting and convection monitoring. In this study, we propose a simplified cloud scattering light model to analyze the influence of inhomogeneities in the cloud microphysical properties on the observations of blue corona discharges (BLUEs) from Atmosphere-Space Interactions Monitor. The results show that the depth inferred from the inhomogeneous model is consistently lower than that from the homogeneous model, with the largest difference reaching 2 km. We then present a new approach to inferring inhomogeneous cloud microphysical profiles based on the optical signals from BLUEs using radio-inferred source depths. These profiles match well with Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation lidar measurements and show a transition nearby tropopause with different exponential change rates above and below it. Our study highlights the potential of combining optical and radio observations of BLUEs to rapidly assess cloud microphysics and monitor convective activity.

AB - Understanding cloud-top microphysics is essential for improving weather forecasting and convection monitoring. In this study, we propose a simplified cloud scattering light model to analyze the influence of inhomogeneities in the cloud microphysical properties on the observations of blue corona discharges (BLUEs) from Atmosphere-Space Interactions Monitor. The results show that the depth inferred from the inhomogeneous model is consistently lower than that from the homogeneous model, with the largest difference reaching 2 km. We then present a new approach to inferring inhomogeneous cloud microphysical profiles based on the optical signals from BLUEs using radio-inferred source depths. These profiles match well with Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observation lidar measurements and show a transition nearby tropopause with different exponential change rates above and below it. Our study highlights the potential of combining optical and radio observations of BLUEs to rapidly assess cloud microphysics and monitor convective activity.

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KW - corona discharges

KW - lightning

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Resolving Inhomogeneous Cloud Microphysics Through Cloud-Top Observations of Blue Corona Discharges

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