A First Look at Cloud Inhomogeneity and Its Effect on Lightning Optical Emission

Optical emission observed from lightning is the result of in‐cloud scattering, lightning channel geometry, and optical energy of the source discharge. To better understand how scattering affects measured optical emission, we developed a Monte Carlo model using an inhomogeneous scattering profile fro...

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Bibliographic Details
Published in:Geophysical research letters 2020-05, Vol.47 (10), p.n/a
Main Authors: Brunner, Kelcy N., Bitzer, Phillip M.
Format: Article
Language:English
Subjects:
Cloud droplet concentration
Cloud droplet size
Cloud droplets
Clouds
Computer simulation
Concentration gradient
Discharge
Droplets
Emission
Emission measurements
Environmental impact
GLM
Graupel
Hail
Height
Ice
Ice particles
Inhomogeneity
Light
Lightning
Lightning channels
Lightning discharges
Microphysics
Monte Carlo
Particle concentration
Particle size distribution
Reflectance
Satellite imagery
Scattering
Size distribution
Statistical methods
thundercloud
Thunderstorms
Water droplets
Water drops
Weather forecasting
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Summary:Optical emission observed from lightning is the result of in‐cloud scattering, lightning channel geometry, and optical energy of the source discharge. To better understand how scattering affects measured optical emission, we developed a Monte Carlo model using an inhomogeneous scattering profile from a simulated storm using two‐moment bulk microphysics in the Weather Research and Forecasting model, including the concentration and size distribution of cloud droplets and ice particles. Within the Monte Carlo model lightning discharges are simulated as point and line sources. These idealized simulations indicate that for a lightning discharge at 7 km altitude approximately 22% and 13% of light, emitted near and away (respectively) from a reflectivity core will reach cloud top in a thunderstorm. The vertical gradient of the microphysical environment impacts light reaching cloud top regardless of overall particle concentration. Increasing cloud ice modifies the gradient of the microphysical profile and modulates the profile gradient effect. Plain Language Summary Measurements of light emitted by lightning are impacted by the cloud, the shape of the lightning channel, and the brightness of the lightning event. In this study we work to understand the impact each of these has on the fraction of the light that reaches cloud top. Understanding the fraction of the light reaching cloud top in a thunderstorm and where it occurs can help us understand how satellite lightning imagers are performing and how light propagates in a cloud. We develop a model using randomization of the scatterers and a cloud adapted from a simulated thunderstorm. The model includes a range of water droplets, ice particles, and their aggregates that change with height and location in the storm. More simulated light is detected at cloud top when lightning is near the center of the thunderstorm and approximately one third less light reaches cloud top when the lightning is located away from the main part of the thunderstorm. The difference between the locations is due to how the scattering length increases or decreases with height, regardless of the overall concentration of all scatterers, including ice, rain, cloud droplets, graupel, hail, or snow. Key Points Lightning source height has the largest effect on scattering in both low and high radar reflectivity regions in thunderstorms Concentration and radii of scatterers has a nonlinear impact on light reaching cloud top The vertical gradient of t
ISSN:0094-8276
1944-8007
DOI:10.1029/2020GL087094