Use of RegCM gridded dataset for thunderstorm favorable conditions analysis over Poland—climatological approach

Walawender, Ewelina; Kielar, Rafal; Ustrnul, Zbigniew

doi:10.1007/s00704-015-1620-x

Cited by 8 publications

(4 citation statements)

References 42 publications

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“…3) The greatest convective instability occurs from June to August between 1400 and 1600 UTC, with the highest lowlevel moisture at 1800 UTC. The results listed above are broadly consistent with prior studies concerning the climatological aspects of lightning (Anderson and Klugmann 2014;Poelman et al 2016;Taszarek et al 2019;Enno et al 2020), convective environments accompanying central European thunderstorms (Púčik et al 2015;Taszarek et al 2020;Walawender et al 2017;Westermayer et al 2017), and the comparison of satellite observations of thunderstorms with ERA-Interim environments over tropical and subtropical regions (Liu et al 2020).…”

Section: Discussionsupporting

confidence: 88%

Diurnal and Seasonal Variability of ERA5 Convective Parameters in Relation to Lightning Flash Rates in Poland

Poręba

Taszarek

Ustrnul

2022

Weather and Forecasting

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The relationship between convective parameters derived from ERA5 and cloud-to-ground (CG) lightning flashes from the PERUN network in Poland was evaluated. All flashes detected between 2002–2019 were divided into intensity categories based on a peak 1-minute CG lightning flash rate and were collocated with proximal profiles from ERA5 to assess their climatological variability. Thunderstorms in Poland are the most frequent in July, between 1400–1600 UTC and over the southeastern parts of the country. The highest median of MUCAPE for CG lightning flash events is from June to August, between 1400–1600 UTC (around 900 J kg−1), whereas patterns in 0–6 km wind shear (DLS) are reversed, with the highest median values during winter and night (around 25 m s−1). The best overlap of MUCAPE and DLS (MUWMAXSHEAR parameter) is in July–August, typically between 1400–2000 UTC with median values of around 850 m2 s−2. Thunderstorms in Poland are the most frequent in MUCAPE below 1000 J kg−1, and DLS between 8–15 m s−1. Along with increasing MUCAPE and DLS, peak CG lightning flash rates increase as well. Compared to DLS, MUCAPE is a more important parameter in forecasting any lightning activity, but when these two are combined together (MUWMAXSHEAR) they are more reliable in distinguishing between thunderstorms producing small and high CG lightning flash rates. Our results also indicate that higher CG lightning flash rates result in thunderstorms more frequently associated with severe weather reports (hail, tornado, wind).

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Section: Discussionsupporting

confidence: 88%

Diurnal and Seasonal Variability of ERA5 Convective Parameters in Relation to Lightning Flash Rates in Poland

Poręba

Taszarek

Ustrnul

2022

Weather and Forecasting

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“…Despite their spatial and temporal scarcity, direct aerological measurements accommodate a straightforward assessment of modeled convective variables. A few studies employed radiosonde observations for climate model verification (Seely and Romps 2015; Walawender et al 2017;Li et al 2020;Rasmussen et al 2020). Frequently utilized environmental proxy parameters include convective available potential energy, convective inhibition, and 0-6 km vertical wind shear.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of convective parameters derived from pressure level and native ERA5 data and different resolution WRF climate simulations over Central Europe

Varga

Breuer

2021

Clim Dyn

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The mean climatological distribution of convective environmental parameters from the ERA5 reanalysis and WRF regional climate simulations is evaluated using radiosonde observations. The investigation area covers parts of Central and Eastern Europe. Severe weather proxies are calculated from daily 1200 UTC sounding measurements and collocated ERA5 and WRF pseudo-profiles in the 1985–2010 period. The pressure level and the native ERA5 reanalysis, and two WRF runs with grid spacings of 50 and 10 km are verified. ERA5 represents convective parameters remarkably well with correlation coefficients higher than 0.9 for multiple variables and mean errors close to zero for precipitable water and mid-tropospheric lapse rate. Monthly mean mixed-layer CAPE biases are reduced in the full hybrid-sigma ERA5 dataset by 20–30 J/kg compared to its pressure level version. The WRF model can reproduce the annual cycle of thunderstorm predictors but with considerably lower correlations and higher errors than ERA5. Surface elevation differences between the stations and the corresponding grid points in the 50-km WRF run lead to biases and false error compensations in the convective indices. The 10-km grid spacing is sufficient to avoid such discrepancies. The evaluation of convection-related parameters contributes to a better understanding of regional climate model behavior. For example, a strong suppression of convective activity might explain precipitation underestimation in summer. A decreasing correlation of WRF-derived wind shear away from the western domain boundaries indicates a deterioration of the large-scale circulation as the constraining effect of the driving reanalysis weakens.

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“…Urban et al 2021;Bandhauer et al 2022) or convective parameters (e.g. Taszarek et al 2021;Walawender et al 2017;Varga et al 2022). A comprehensive evaluation of upper air parameters is, as far as our knowledge, missing.…”

Section: Reanalysis and Radiosondesmentioning

confidence: 99%

On the relation of CMIP6 GCMs errors at RCM driving boundary condition zones and inner domain for Central Europe region

Holtanová,

Belda,

Crespo

et al. 2023

Preprint

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Global climate models (GCMs) are important tools for studying the climate system and climate change projections. Due to their coarse spatial resolution, downscaling is necessary on regional scale. Regional climate models (RCMs) represent a common solution for this issue. Nevertheless, outputs of RCMs are influenced by the boundary conditions provided by GCMs. This study evaluates CMIP6 GCMs regarding the variables relevant as RCM boundary conditions. Special focus is on the simulation of CNRM-ESM2-1, which is being used as a driving model for convection-permitting Aladin-Climate/CZ RCM, used as one source feeding new Czech climate change scenarios. The analysis is conducted over the boundaries and inside the RCM integration domain. Firstly, an evaluation of CFSR and ERA5 reanalyses against radiosondes is performed in order to choose an appropriate reference dataset for upper air variables. Revealed high correlation between both reanalysis and radiosondes slightly decreases at the most upper tropospheric levels. ERA5 is then chosen as the reference for the boundary analysis. Over the inner domain, simulated mean annual cycle of impact-relevant variables is validated against E-OBS. The CNRM-ESM2-1 performs well in terms of near-surface variables over the Czech Republic, but it exhibits larger errors along the boundaries, especially for air temperature and specific humidity. Weak statistical relationship between the GCM performance over the boundaries in the upper levels and over the inner domain suggests that the nested RCM simulation does not necessarily have to be influenced by the biases in the driving data.

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Use of RegCM gridded dataset for thunderstorm favorable conditions analysis over Poland—climatological approach

Cited by 8 publications

References 42 publications

Diurnal and Seasonal Variability of ERA5 Convective Parameters in Relation to Lightning Flash Rates in Poland

Diurnal and Seasonal Variability of ERA5 Convective Parameters in Relation to Lightning Flash Rates in Poland

Evaluation of convective parameters derived from pressure level and native ERA5 data and different resolution WRF climate simulations over Central Europe

On the relation of CMIP6 GCMs errors at RCM driving boundary condition zones and inner domain for Central Europe region

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