Observations and WRF simulations of fog events at the Spanish Northern Plateau

Román‐Cascón, Carlos; Yagüe, Carlos; Sastre, Mariano; Maqueda, Gregorio; Salamanca, Francisco; Viana, Samuel

doi:10.5194/asr-8-11-2012

Cited by 58 publications

(24 citation statements)

References 11 publications

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“…For the microphysics scheme, the WRF double-moment sixclass (WDM6) was used. The Mellor-Yamada-Nakanishi-Niino (MYNN) 2.5-level parametrization (Nakanishi and Niino, 2004) was used for the PBL and surface layer schemes, which has also been proved to perform adequately for fog conditions (Román-Cascón et al, 2012). RRTM (Mlawer et al, 1997) and Dudhia (1989) parametrizations were used for short-wave and long-wave radiation respectively.…”

Section: Numerical Fog Forecasting (Wrf-arw Model)mentioning

confidence: 99%

“…Many studies analyse the sensitivity of NWP models to different technical configurations or physical parametrizations (e.g. Bergot and Guedalia, ; Pagowski et al , ; Van der Velde et al , ; Román‐Cascón et al , ). Thus, there is a continuous effort by the modelling community to improve fog forecasting through the incorporation of new physical parametrizations (e.g.…”

Section: Introductionmentioning

confidence: 99%

“…Despite the numerous influences of fog on daily life, it is still poorly forecasted by numerical weather prediction (NWP) models (Bergot et al, 2007;Müller et al, 2010;Román-Cascón et al, 2012;Price et al, 2015;Steeneveld et al, 2015). One of the causes of the unsuccessful prediction of fog is the interaction of several processes (Gultepe et al, 2009): radiative cooling during fog formation and heating during fog dissipation, pre-fog turbulence intensity, turbulence generated by fog itself (Cuxart and Jiménez, 2012), synoptic advection, concentration of cloud condensation nuclei (CCN), surface water availability, synopticscale conditions and local features of the area, influencing local winds, nearby advections, etc.…”

Section: Introductionmentioning

confidence: 99%

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Forecasting radiation fog at climatologically contrasting sites: evaluation of statistical methods and WRF

Román‐Cascón

Steeneveld

Yagüe

et al. 2016

Quart J Royal Meteoro Soc

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A six‐year climatology of radiation fog has been compiled at two sites: the Research Centre for the Lower Atmosphere (CIBA, Spain) and the Cabauw Experimental Site for Atmospheric Research (CESAR, The Netherlands). These sites are contrasted in terms of geographical situation, climate zone, altitude, humidity and soil water availability. Therefore, several climatological differences in fog abundance, onset, dissipation and duration have been quantified between the two sites. The more humid site (CESAR) is characterised by relatively short radiation fog events distributed throughout the year. However, radiation fog at the drier site (CIBA) is more persistent and appears during late autumn/winter months. In general, its formation requires more time after sunset (∼2 h more), since further cooling is required to reach saturation. The forecast of these fog events has been evaluated through two different approaches. First, we extend the statistical method presented by Menut et al. (2014) (M14). This method uses statistics to define threshold values on key variables for fog formation (pre‐fog) and verifies its predictability using observations and numerical model output. We present some of the most appropriate threshold values for the forecasting of pre‐fog periods at both sites, which differ from those presented in M14 and depend on the optimisation of the hit rate or the false‐alarm rate. Additionally, we also extend M14 by suggesting other variables as potential predictors for fog formation (friction velocity and visibility tendency). Finally, we focus on fog simulation by the Weather Research and Forecasting (WRF) model in terms of liquid water content. The WRF model was able to simulate radiation fog when configured with sophisticated physical options and high resolution. However it failed in simulating the onset, dissipation and the vertical extent of fog (which was overestimated). The model results were extremely sensitive to the spin‐up time.

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Section: Numerical Fog Forecasting (Wrf-arw Model)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Forecasting radiation fog at climatologically contrasting sites: evaluation of statistical methods and WRF

Román‐Cascón

Steeneveld

Yagüe

et al. 2016

Quart J Royal Meteoro Soc

Self Cite

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show abstract

“…Thus, mesoscale NWP models need to simulate correctly all these physical processes to perform successful simulations of fog. However, the fog forecasting can be also affected by issues related to the model itself: possible errors in initial and boundary conditions (e.g., Bergot and Guedalia, 1994;Hu et al, 2014), appropriate spin-up times (e.g., Román-Cascón et al, 2016a), limitations in the vertical/horizontal resolution (e.g., Philip et al, 2016;Boutle et al, 2016) or inappropriate parameterizations of sub-grid scale processes (e.g., Román-Cascón et al, 2012;Chaouch et al, 2017). These are some of the reasons why in other cases, the use of 1D models and statistical downscaling techniques are also used, especially in predictions needed at specific points, e.g., in airports (Cornejo-Bueno et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Radiation and cloud-base lowering fog events: Observational analysis and evaluation of WRF and HARMONIE

Román‐Cascón

Yagüe

Steeneveld

et al. 2019

Atmospheric Research

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Most of the effects caused by fog are negative for humans. Yet, numerical weather prediction (NWP) models still have problems to simulate fog properly, especially in operational forecasts. In the case of radiation fog, this is partially caused by the large sensitivity to many aspects that contribute to its formation, evolution and dissipation, such as the synoptic and local conditions, the near-surface turbulence, the aerosol and droplet microphysics, or the surface characteristics, among others. This work focuses on an interesting 8-day period with several alternating radiation and cloud-base lowering (CBL) fog events observed at the Research Centre for the Lower Atmosphere (CIBA) in the Spanish Northern Plateau. The site was appropriately instrumented to characterize fog from the surface up to the height of 100 m. On the one hand, radiation fog events are associated with strong surface cooling leading to high stability close to the surface and low values of turbulence, giving rise to shallow fog. The evolution of this type of fog is markedly sensitive to the dynamical conditions close to the surface (i.e., wind speed and turbulence). On the other hand, CBL fog presents deeper thickness associated with higher values of turbulence and less stability. Subsequently, we evaluated the fog-forecasting skill of two mesoscale models (WRF and HARMONIE) configured as similar as possible. Both models present more difficulties simulating radiation fog events than CBL ones. However, the duration and vertical extension of the CBL fog events is normally overestimated. This extended-fog avoids the surface radiative cooling needed to simulate radiation fog events formed the following nights. Therefore, these periods with alternating CBL and radiation fog are especially challenging for NWP models.

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“…E-mail: pgoswami@nistads.res.in model (COBEL-ISBA) and an ensemble system showed the forecasts to be very sensitive to local initial conditions and mesoscale forcings (Roquelaure and Bergot, 2008). Despite the major economic impact of radiation fog on human society, numerical weather prediction models have relatively low skill in forecasting both the onset and the development of radiation fog (Teixeira, 1999;Gultepe et al, 2007;Tudor, 2010;Zhou et al, 2011;Román-Cascón et al, 2012). Forecasting radiation fog is still somewhat problematic because local topography, moisture availability, vegetation and soil conditions introduce spatial variability into the model results and forecast products (Golding, 1993;Meyer and Rao, 1999).…”

Section: Introductionmentioning

confidence: 99%

An analogue dynamical model for forecasting fog‐induced visibility: validation over Delhi

Goswami

Sarkar

2017

Meteorological Applications

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Accurate forecasts of fog and visibility are important for many applications; while prolonged fog can adversely affect many crops, even a short duration of dense fog can lead to disruption of air and highway traffic. The genesis and dynamics of fog are a result of many processes; accurate forecasting of fog thus continues to be a challenge. A forecast model of the occurrence of fog, measured in terms of visibility, is presented. The model is formulated as an analogue model; thus the merit of the model is primarily based on its validation against observation. Two forecasts using two sets of meteorological fields are considered: one as the benchmark forecasts with visibility calculated from observed meteorological fields and the other based on meteorological forecasts from an atmospheric mesoscale model (Weather Research and Forecasting). While the benchmark (perfect) forecasts from observed meteorological fields provide the potential skill of the model, the mesoscale forecasts provide an assessment of realizable skill in an operational setting. The validation was carried out against hourly visibility data recorded at Indira Gandhi International Airport over Delhi during the winter months (December and January) for the period 2009–2012. Error statistics show that the analogue fog model can capture a significant part of the observed variability of fog. The forecasts have more success in forecasting intense (visibility < 500 m) and persistent (duration > 4 h) fog events. The model provides a useful forecasting tool, as shown by measures such as average error, number of false warnings and the number of misses.

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Observations and WRF simulations of fog events at the Spanish Northern Plateau

Cited by 58 publications

References 11 publications

Forecasting radiation fog at climatologically contrasting sites: evaluation of statistical methods and WRF

Forecasting radiation fog at climatologically contrasting sites: evaluation of statistical methods and WRF

Radiation and cloud-base lowering fog events: Observational analysis and evaluation of WRF and HARMONIE

An analogue dynamical model for forecasting fog‐induced visibility: validation over Delhi

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