Aircraft wind measurements to assess a coupled <scp>WRF‐CALMET</scp> mesoscale system

Gioli, Beniamino; Gualtieri, Giovanni; Busillo, C.; Calastrini, F.; Gozzini, Bernardo; Miglietta, Franco

doi:10.1002/met.1419

Cited by 14 publications

(8 citation statements)

References 42 publications

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“…As the aircraft observations include high frequency PBL turbulence fluctuations that are filtered out in the WRF model results as a subgrid scale turbulent component of meteorological variables, this reproduction is proving the model's ability to simulate the conditions on a smaller scale aptly. Overall, the findings of the present study are consistent with Gioli et al [65], indicating that the sea breeze transition is a critical phenomenon to be correctly simulated in time and space with a WRF-based modeling setup.…”

Section: Discussionsupporting

confidence: 92%

“…As evidenced by the discussion of WRF results at each measured profile location, the variability in model errors is more related to both the spatial and temporal variability of atmospheric properties than to the behavior of the different PBL schemes. Overall, our findings are consistent with Gioli et al [65], indicating that sea breeze transition is a critical phenomenon to be correctly simulated in time and space with a WRF-based modeling setup. However, these results allow the identification of a subset of PBL schemes that perform comparably, and constitute useful data to constrain the choice of the PBL scheme in the setup of a WRF modeling chain for meteorological or air quality predictions.…”

Section: Acm2supporting

confidence: 92%

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Performance Analysis of Planetary Boundary Layer Parameterization Schemes in WRF Modeling Set Up over Southern Italy

Tyagi

Magliulo

Finardi³

et al. 2018

Atmosphere

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Predictions of boundary layer meteorological parameters with accuracy are essential for achieving good weather and air quality regional forecast. In the present work, we have analyzed seven planetary boundary layer (PBL) parameterization schemes in a Weather Research and Forecasting (WRF) model over the Naples-Caserta region of Southern Italy. WRF model simulations were performed with 1-km horizontal resolution, and the results were compared against data collected by the small aircraft Sky Arrow Environmental Research Aircraft (ERA) during 7–9 October 2014. The selected PBL schemes include three first-order closure PBL schemes (ACM2, MRF, YSU) and four turbulent kinetic energy (TKE) closure schemes (MYJ, UW, MYNN2, and BouLac). A performance analysis of these PBL schemes has been investigated by validating them with aircraft measurements of meteorological parameters profiles (air temperature, specific humidity, wind speed, wind direction) and PBL height to assess their efficiency in terms of the reproduction of observed weather conditions. Results suggested that the TKE closure schemes perform better than first-order closure schemes, and the MYNN2 closure scheme is close to observed values most of the time. It is observed that the inland locations are better simulated than sea locations, and the morning periods are better simulated than those in the afternoon. The results are emphasizing that meteorology-induced variability is larger than the variability in PBL schemes.

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Section: Discussionsupporting

confidence: 92%

Section: Acm2supporting

confidence: 92%

Performance Analysis of Planetary Boundary Layer Parameterization Schemes in WRF Modeling Set Up over Southern Italy

Tyagi

Magliulo

Finardi³

et al. 2018

Atmosphere

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“…These discrepancies may be ascribed to breeze regimes: the misrepresentation of wind speed magnitude during a sea breeze with the WRF was reported, among others, by Hernández-Ceballos et al (2013) while simulating breeze conditions in the Guadalquivir Valley. The aircraft data set presented here was used by Gioli et al (2014) to validate a modelling chain using the WRF (Non-Hydrostatic Mesoscale Model v.2.1 initialized with the NCEP-GFS) and CALMET (Scire et al, 2000), and a similar influence of the breeze regime was also reported. In that work, the largest differences were observed in coastal areas in summer where breeze regimes develop consistently.…”

Section: Discussionmentioning

confidence: 96%

“…The region's climate is typically Mediterranean, with mean annual rainfall between 700 and 1,000 mm and average annual temperature around 14-16 C. According to the Corine Land Cover 2006 classification (ISPRA, 2010) the flight area is dominated by forest and agricultural land. The orography is generally flat on the coast and becomes more variable moving from the southwest to the northeast inner area, reaching a peak altitude of 600 masl, while the final inland part is moderately hilly (Gioli et al, 2014). The experimental plan for the flights, originally designed for measuring carbon fluxes at a regional scale for the CARBIUS project (Maselli et al, 2010), was based on a set of IOPs in different seasons of the year, over a repetitive path and in different times of the day, therefore sampling both spatial and temporal variability.…”

Section: Study Area and Aircraft Measurementsmentioning

confidence: 99%

WRF wind field assessment under multiple forcings using spatialized aircraft data

Carotenuto

Gualtieri

Toscano

et al. 2020

Meteorological Applications

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The performances of limited area weather models are affected by the choice of core solvers, domain resolutions, and initial and boundary conditions. To understand the extent of such differences on simulated wind fields, weather research and forecast (WRF) simulations initialized by different forcings were extensively compared with an aircraft-derived high-resolution data set. The two used forcings were the European Centre for Medium-Range Weather Forecasts (ECMWF) ERA-Interim reanalysis and the National Centers for Environmental Predictions (NCEP) Climate Forecast System Reanalysis (CFSR). The model domain covered a large portion of central western Italy (including part of the Tyrrhenian coast) encompassing the aircraft track and allowed the characterization of their performance across the simulation domain rather than a small set of point-based observations. The WRF results show good agreement with the aircraft data across the whole flight track with both forcings (root mean square errors (RMSEs) < 2.3 m•s −1 and an average r 2 = 0.7). Orography and coasts show an effect on simulated wind fields. The presence of a strong orography (which is smoothed by the model internal terrain elevation model) is associated with increased errors. Distance from the coast is also associated with a variation in RMSE (even if in a non-straightforward manner) because of potential breeze effects. No forcing data set clearly outperforms the other, while the ECMWF has higher correlation coefficients when considering wind direction.

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“…Despite the potential improvement in spatial resolution and trajectory simulation, there are still biases in computed trajectories due to non-perfect matching between meteorological transport fields and real meteorological situations (type I error), as well as due to their limited spatio-temporal resolution (type II errors) (Bowman et al 2013 ). In this regard, Gioli et al ( 2014b ) performed a detailed comparison of the WRF/CALMET modelling chain against aircraft measurements, finding that model performance varied depending on season, land use and orography, with overall agreements ranging between 2% (inland, hilly areas) and 31% (coastal areas).…”

Section: Introductionmentioning

confidence: 99%

Industrial point source CO2 emission strength estimation with aircraft measurements and dispersion modelling

Carotenuto

Gualtieri

Miglietta

et al. 2018

Environ Monit Assess

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CO2 remains the greenhouse gas that contributes most to anthropogenic global warming, and the evaluation of its emissions is of major interest to both research and regulatory purposes. Emission inventories generally provide quite reliable estimates of CO2 emissions. However, because of intrinsic uncertainties associated with these estimates, it is of great importance to validate emission inventories against independent estimates. This paper describes an integrated approach combining aircraft measurements and a puff dispersion modelling framework by considering a CO2 industrial point source, located in Biganos, France. CO2 density measurements were obtained by applying the mass balance method, while CO2 emission estimates were derived by implementing the CALMET/CALPUFF model chain. For the latter, three meteorological initializations were used: (i) WRF-modelled outputs initialized by ECMWF reanalyses; (ii) WRF-modelled outputs initialized by CFSR reanalyses and (iii) local in situ observations. Governmental inventorial data were used as reference for all applications. The strengths and weaknesses of the different approaches and how they affect emission estimation uncertainty were investigated. The mass balance based on aircraft measurements was quite succesful in capturing the point source emission strength (at worst with a 16% bias), while the accuracy of the dispersion modelling, markedly when using ECMWF initialization through the WRF model, was only slightly lower (estimation with an 18% bias). The analysis will help in highlighting some methodological best practices that can be used as guidelines for future experiments.

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Aircraft wind measurements to assess a coupled WRF‐CALMET mesoscale system

Cited by 14 publications

References 42 publications

Performance Analysis of Planetary Boundary Layer Parameterization Schemes in WRF Modeling Set Up over Southern Italy

Performance Analysis of Planetary Boundary Layer Parameterization Schemes in WRF Modeling Set Up over Southern Italy

WRF wind field assessment under multiple forcings using spatialized aircraft data

Industrial point source CO2 emission strength estimation with aircraft measurements and dispersion modelling

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