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Observations and numerical simulations of a valley-exit wind in the Alpine Bolzano basin

Federica Gucci, Andrea Zonato, Marco Falocchi, Dino Zardi, Lorenzo Giovannini

Abstract

The characteristics of the nocturnal drainage wind flowing from the tributary Isarco Valley into the Bolzano basin, in the Italian Alps, during wintertime are investigated. Analyses are performed by combining measurements from an intensive field campaign and the output of four high-resolution numerical simulations, run with the Weather Research and Forecasting (WRF) model using different planetary boundary-layer (PBL) schemes. Two episodes are identified, based on the vertical temperature stratification in the basin and the evolution of the drainage flow at the valley exit. Numerical results show that the drainage flow behaves as a valley-exit wind, whose main structure at the exit of the valley is well captured by the model independently of the PBL scheme. However, the model struggles to correctly reproduce the temperature stratification in the basin, with better results when a PBL scheme including, among others, a prognostic equation for the temperature variance and a counter-gradient term is used. This has an impact on the simulation of the onset and duration of the valley-exit wind, which are sensitive to the temperature contrasts between the valley and the basin. Overall, the model is able to reproduce the different behavior of the drainage wind at the exit of the valley in the two case studies. It is found that the presence of a cold air pool in the basin favors an upward trajectory of the flow at the exit of the valley, resulting in unperturbed calm wind conditions in the lower levels. On the other hand, with weak temperature stratification, the drainage flow closely follows the topography, resulting in strong winds also near the surface.

Observations and numerical simulations of a valley-exit wind in the Alpine Bolzano basin

Abstract

The characteristics of the nocturnal drainage wind flowing from the tributary Isarco Valley into the Bolzano basin, in the Italian Alps, during wintertime are investigated. Analyses are performed by combining measurements from an intensive field campaign and the output of four high-resolution numerical simulations, run with the Weather Research and Forecasting (WRF) model using different planetary boundary-layer (PBL) schemes. Two episodes are identified, based on the vertical temperature stratification in the basin and the evolution of the drainage flow at the valley exit. Numerical results show that the drainage flow behaves as a valley-exit wind, whose main structure at the exit of the valley is well captured by the model independently of the PBL scheme. However, the model struggles to correctly reproduce the temperature stratification in the basin, with better results when a PBL scheme including, among others, a prognostic equation for the temperature variance and a counter-gradient term is used. This has an impact on the simulation of the onset and duration of the valley-exit wind, which are sensitive to the temperature contrasts between the valley and the basin. Overall, the model is able to reproduce the different behavior of the drainage wind at the exit of the valley in the two case studies. It is found that the presence of a cold air pool in the basin favors an upward trajectory of the flow at the exit of the valley, resulting in unperturbed calm wind conditions in the lower levels. On the other hand, with weak temperature stratification, the drainage flow closely follows the topography, resulting in strong winds also near the surface.
Paper Structure (13 sections, 16 figures, 4 tables)

This paper contains 13 sections, 16 figures, 4 tables.

Table of Contents

  1. Introduction
  2. Study area and experimental measurements
  3. The Bolzano basin
  4. BTEX experiment
  5. Case studies
  6. Model setup
  7. PBL schemes intercomparison
  8. 28-29 January 2017: Episode 1
  9. Quantitative evaluation of model results
  10. 13-14 February 2017: Episode 2
  11. Quantitative evaluation of model results
  12. Spatial characteristics of the valley-exit wind and interaction with the CAP
  13. Conclusions

Figures (16)

  • Figure 1: Area of study: (a) Map of the three nested domains used for the WRF simulations, and (b) zoom in the innermost domain, with the location of the instruments used to evaluate model results, i.e. lidar, temperature profiler (MTP), and 11 ground weather stations (BR: Bronzolo, BO: Bolzano, GA: Gargazzone, ME: Merano, BC: Barbiano-Colma, CA: Caldaro, BS: Bressanone, FS: Fié allo Sciliar, SA: Sarentino, SG: San Genesio, NP: Nova Ponente). (c, d) Photo and aerial photo of the basin and the city of Bolzano with mountain crests surrounding the basin.
  • Figure 2: Monthly evolution of hourly temperature differences between 450m and 250m a.s.l. (200 m AGL and the surface) from temperature profiler measurements in (a) January and (b) February. Monthly evolution of the hourly west-east component of the 10-m wind speed measured at Bolzano GWS (see Fig. \ref{['fig: Map domains']}b), in (c) January and (d) February.
  • Figure 3: Time-height plots of temperature for Episode 1 at the temperature profiler site as (a) measured and simulated by (b) YSU, (c) MYJ, (d) BouLac and (e) KEPS-TPE.
  • Figure 4: Time-height plots of horizontal wind speed for Episode 1 at the lidar site as (a) measured and simulated by (b) YSU, (c) MYJ, (d) BouLac and (e) KEPS-TPE
  • Figure 5: Time-height plots of horizontal wind direction for Episode 1 at the lidar site as (a) measured and simulated by (b) YSU, (c) MYJ, (d) BouLac and (e) KEPS-TPE.
  • ...and 11 more figures