Modeling the Flash Rate of Thunderstorms. Part II: Implementation

In Part I of this two-part paper a new method of predicting the total lightning flash rate in thunderstorms was introduced. In this paper, the implementation of this method into the convection-permitting Consortium for Small Scale Modeling (COSMO) model is presented. The new approach is based on a s...

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Bibliographic Details
Published in:Monthly weather review 2011-10, Vol.139 (10), p.3112-3124
Main Authors: DAHL, Johannes M. L, HOLLER, Hartmut, SCHUMANN, Ulrich
Format: Article
Language:English
Subjects:
Algorithms
Atmospheric electricity
Convection
Convective clouds
Cumulonimbus clouds
Dipoles
Discharge
Earth, ocean, space
Exact sciences and technology
External geophysics
Ice
Leakage current
Lightning
Lightning activity
Lightning detection
Lightning detection networks
Lightning flashes
Meteorology
Modelling
Simulation
Small-scale models
Swaths
Thunderstorms
Velocity
Weather
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Summary:In Part I of this two-part paper a new method of predicting the total lightning flash rate in thunderstorms was introduced. In this paper, the implementation of this method into the convection-permitting Consortium for Small Scale Modeling (COSMO) model is presented. The new approach is based on a simple theoretical model that consists of a dipole charge structure, which is maintained by a generator current and discharged by lightning and, to a small extent, by a leakage current. This approach yields a set of four predictor variables, which are not amenable to direct observations and consequently need to be parameterized (Part I). Using an algorithm that identifies thunderstorm cells and their properties, this approach is applied to determine the flash frequency of every thunderstorm cell in the model domain. With this information, the number of flashes that are accumulated by each cell and during the interval between the activation of the lightning scheme can be calculated. These flashes are then randomly distributed in time and beneath each cell. The output contains the longitude, the latitude, and the time of occurrence of each simulated discharge. Simulations of real-world scenarios are presented, which are compared to measurements with the lightning detection network, LINET. These comparisons are done on the cloud scale as well as in a mesoscale region composing southern Germany (two cases each). The flash rates of individual cumulonimbus clouds at the extreme ends of the intensity spectrum are realistically simulated. The simulated overall lightning activity over southern Germany is dominated by spatiotemporal displacements of the modeled convective clouds, although the scheme generally reproduces realistic patterns such as coherent lightning swaths.
ISSN:0027-0644
1520-0493
DOI:10.1175/MWR-D-10-05032.1