J
Jean-Pierre Pinty
Researcher at University of Toulouse
Publications - 64
Citations - 3366
Jean-Pierre Pinty is an academic researcher from University of Toulouse. The author has contributed to research in topics: Mesoscale meteorology & Lightning. The author has an hindex of 30, co-authored 64 publications receiving 3163 citations. Previous affiliations of Jean-Pierre Pinty include Paul Sabatier University & Centre national de la recherche scientifique.
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Journal ArticleDOI
The Meso-NH Atmospheric Simulation System. Part I: adiabatic formulation and control simulations
Jean-Philippe Lafore,Joël Stein,Nicole Asencio,Philippe Bougeault,Véronique Ducrocq,J. Duron,C. Fischer,P. Héreil,Patrick Mascart,Valéry Masson,Jean-Pierre Pinty,Jean-Luc Redelsperger,Evelyne Richard,J. Vilà-Guerau de Arellano +13 more
TL;DR: The Meso-NH Atmospheric Simulation Engine as mentioned in this paper is a tool for small and meso-scale atmospheric processes, which is based on the Lipps and Hemler form of the anelastic system.
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A comprehensive two‐moment warm microphysical bulk scheme. I: Description and tests
TL;DR: In this article, a bulk microphysical scheme which predicts the concentrations and mixing ratios of cloud droplets and raindrops is presented, which draws its originality from the use of generalized gamma law as basis functions for the drop size distributions.
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High-Resolution Non-Hydrostatic Simulations of Flash-Flood Episodes with Grid-Nesting and Ice-Phase Parameterization
TL;DR: In this paper, simulations of two heavy rainfall events south of the Alps have been conducted with a non-hydrostatic model at horizontal resolutions ranging from 40 to 2.5 km.
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Extending Twomey’s Analytical Estimate of Nucleated Cloud Droplet Concentrations from CCN Spectra
TL;DR: In this paper, the authors follow Twomey's theoretical approach but using a more realistic four-parameter CCN activation spectrum as shaped by the physicochemical properties of the accumulation mode in a natural aerosol population.
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A Comparison of TWP-ICE Observational Data with Cloud-Resolving Model Results
Ann M. Fridlind,Andrew S. Ackerman,Jean-Pierre Chaboureau,Jiwen Fan,Wojciech W. Grabowski,Adrian R. Hill,Todd R. Jones,Mandana M. Khaiyer,Guosheng Liu,Patrick Minnis,Hugh Morrison,Louis Nguyen,S. Park,S. Park,Jon Petch,Jean-Pierre Pinty,Courtney Schumacher,Ben Shipway,Adam Varble,Xiaoqing Wu,Shaocheng Xie,Minghua Zhang +21 more
TL;DR: In this paper, the TWP-ICE campaign was used to drive and evaluate thirteen cloud-resolving model simulations with periodic lateral boundary conditions, which employed 2D and 3D dynamics, one-and two-moment microphysics, several variations on large-scale forcing, and the use of observationally derived aerosol properties to prognose droplet numbers.