Your search keyword '"Darbieu, C."' showing total 14 results

1. The BLLAST field experiment: Boundary-Layer Late Afternoon and Sunset Turbulence

Author

Lothon, M, Lohou, F, Pino, D, Couvreux, F, Pardyjak, ER, Reuder, J, de Arellano, J Vilà-Guerau, Durand, P, Hartogensis, O, Legain, D, Augustin, P, Gioli, B, Lenschow, DH, Faloona, I, Yagüe, C, Alexander, DC, Angevine, WM, Bargain, E, Barrié, J, Bazile, E, Bezombes, Y, Blay-Carreras, E, van de Boer, A, Boichard, JL, Bourdon, A, Butet, A, Campistron, B, de Coster, O, Cuxart, J, Dabas, A, Darbieu, C, Deboudt, K, Delbarre, H, Derrien, S, Flament, P, Fourmentin, M, Garai, A, Gibert, F, Graf, A, Groebner, J, Guichard, F, Jiménez, MA, Jonassen, M, van den Kroonenberg, A, Magliulo, V, Martin, S, Martinez, D, Mastrorillo, L, Moene, AF, Molinos, F, Moulin, E, Pietersen, HP, Piguet, B, Pique, E, Román-Cascón, C, Rufin-Soler, C, Saïd, F, Sastre-Marugán, M, Seity, Y, Steeneveld, GJ, Toscano, P, Traullé, O, Tzanos, D, Wacker, S, Wildmann, N, and Zaldei, A

Subjects

Earth Sciences, Atmospheric Sciences, Astronomical and Space Sciences, Meteorology & Atmospheric Sciences, Atmospheric sciences, Climate change science

Abstract

Due to the major role of the sun in heating the earth's surface, the atmospheric planetary boundary layer over land is inherently marked by a diurnal cycle. The afternoon transition, the period of the day that connects the daytime dry convective boundary layer to the night-time stable boundary layer, still has a number of unanswered scientific questions. This phase of the diurnal cycle is challenging from both modelling and observational perspectives: it is transitory, most of the forcings are small or null and the turbulence regime changes from fully convective, close to homogeneous and isotropic, toward a more heterogeneous and intermittent state. These issues motivated the BLLAST (Boundary-Layer Late Afternoon and Sunset Turbulence) field campaign that was conducted from 14 June to 8 July 2011 in southern France, in an area of complex and heterogeneous terrain. A wide range of instrumented platforms including full-size aircraft, remotely piloted aircraft systems, remote-sensing instruments, radiosoundings, tethered balloons, surface flux stations and various meteorological towers were deployed over different surface types. The boundary layer, from the earth's surface to the free troposphere, was probed during the entire day, with a focus and intense observation periods that were conducted from midday until sunset. The BLLAST field campaign also provided an opportunity to test innovative measurement systems, such as new miniaturized sensors, and a new technique for frequent radiosoundings of the low troposphere. Twelve fair weather days displaying various meteorological conditions were extensively documented during the field experiment. The boundary-layer growth varied from one day to another depending on many contributions including stability, advection, subsidence, the state of the previous day's residual layer, as well as local, meso-or synoptic scale conditions. Ground-based measurements combined with tethered-balloon and airborne observations captured the turbulence decay from the surface throughout the whole boundary layer and documented the evolution of the turbulence characteristic length scales during the transition period. Closely integrated with the field experiment, numerical studies are now underway with a complete hierarchy of models to support the data interpretation and improve the model representations.

Published

2014

2. Turbulence vertical structure of the boundary layer during the afternoon transition

Author

Darbieu, C., Lohou, F., Lothon, M., de Arellano, J. Vila-Guerau, Couvreux, F., Durand, P., Pino, D., Patton, E. G., Nilsson, Erik, Blay-Carreras, E., Gioli, B., Darbieu, C., Lohou, F., Lothon, M., de Arellano, J. Vila-Guerau, Couvreux, F., Durand, P., Pino, D., Patton, E. G., Nilsson, Erik, Blay-Carreras, E., and Gioli, B.

Abstract

We investigate the decay of planetary boundary layer (PBL) turbulence in the afternoon, from the time the surface buoyancy flux starts to decrease until sunset. Dense observations of mean and turbulent parameters were acquired during the Boundary Layer Late Afternoon and Sunset Turbulence (BLLAST) field experiment by several meteorological surface stations, sounding balloons, radars, lidars and two aircraft during the afternoon transition. We analysed a case study based on some of these observations and large-eddy simulation (LES) data focusing on the turbulent vertical structure throughout the afternoon transition. The decay of turbulence is quantified through the temporal and vertical evolution of (1) the turbulence kinetic energy (TKE), (2) the characteristic length scales of turbulence and (3) the shape of the turbulence spectra. A spectral analysis of LES data, airborne and surface measurements is performed in order to characterize the variation in the turbulent decay with height and study the distribution of turbulence over eddy size. This study highlights the LES ability to reproduce the turbulence evolution throughout the afternoon. LESs and observations agree that the afternoon transition can be divided in two phases: (1) a first phase during which the TKE decays at a low rate, with no significant change in turbulence characteristics, and (2) a second phase characterized by a larger TKE decay rate and a change in spectral shape, implying an evolution of eddy size distribution and energy cascade from low to high wave number. The changes observed either in TKE decay (during the first phase) or in the vertical wind spectra shape (during the second phase of the afternoon transition) occur first in the upper region of the PBL. The higher within the PBL, the stronger the spectra shape changes.

Published

2015

3. Turbulence Kinetic Energy budget during the afternoon transition – Part 1: Observed surface TKE budget and boundary layer description for 10 intensive observation period days

Author

Nilsson, E., primary, Lohou, F., additional, Lothon, M., additional, Pardyjak, E., additional, Mahrt, L., additional, and Darbieu, C., additional

Published

2015

4. Turbulence Kinetic Energy budget during the afternoon transition – Part 2: A simple TKE model

Author

Nilsson, E., primary, Lothon, M., additional, Lohou, F., additional, Pardyjak, E., additional, Hartogensis, O., additional, and Darbieu, C., additional

Published

2015

5. Turbulence vertical structure of the boundary layer during the afternoon transition

Author

Darbieu, C., primary, Lohou, F., additional, Lothon, M., additional, Vilà-Guerau de Arellano, J., additional, Couvreux, F., additional, Durand, P., additional, Pino, D., additional, Patton, E. G., additional, Nilsson, E., additional, Blay-Carreras, E., additional, and Gioli, B., additional

Published

2015

6. Role of the residual layer and large-scale subsidence on the development and evolution of the convective boundary layer

Author

Blay-Carreras, E., Pino, D., Vilà-Guerau de Arellano, J., van de Boer, A., de Coster, O., Darbieu, C., Hartogensis, O.K., Lohou, F., Lothon, M., Pietersen, H.P., Blay-Carreras, E., Pino, D., Vilà-Guerau de Arellano, J., van de Boer, A., de Coster, O., Darbieu, C., Hartogensis, O.K., Lohou, F., Lothon, M., and Pietersen, H.P.

Abstract

Observations, mixed-layer theory and the Dutch Large-Eddy Simulation model (DALES) are used to analyze the dynamics of the boundary layer during an intensive operational period (1 July 2011) of the Boundary Layer Late Afternoon and Sunset Turbulence campaign. Continuous measurements made by remote sensing and in situ instruments in combination with radio soundings, and measurements done by remotely piloted aircraft systems and two manned aircrafts probed the vertical structure and the temporal evolution of the boundary layer during the campaign. The initial vertical profiles of potential temperature, specific humidity and wind, and the temporal evolution of the surface heat and moisture fluxes prescribed in the models runs are inspired by some of these observations. The research focuses on the role played by the residual layer during the morning transition and by the large-scale subsidence on the evolution of the boundary layer. By using DALES, we show the importance of the dynamics of the boundary layer during the previous night in the development of the boundary layer at the morning. DALES numerical experiments including the residual layer are capable of modeling the observed sudden increase of the boundary-layer depth during the morning transition and the subsequent evolution of the boundary layer. These simulations show a large increase of the entrainment buoyancy flux when the residual layer is incorporated into the mixed layer. We also examine how the inclusion of the residual layer above a shallow convective boundary layer modifies the turbulent kinetic energy budget. Large-scale subsidence mainly acts when the boundary layer is fully developed, and, for the studied day, it is necessary to be considered to reproduce the afternoon observations. Finally, we also investigate how carbon dioxide (CO2) mixing ratio stored the previous night in the residual layer plays a fundamental role in the evolution of the CO2 mixing ratio during the following day.

Published

2014

7. Turbulence vertical structure of the boundary layer during the afternoon transition

Author

Darbieu, C., primary, Lohou, F., additional, Lothon, M., additional, Vilà-Guerau de Arellano, J., additional, Couvreux, F., additional, Durand, P., additional, Pino, D., additional, G. Patton, E., additional, Nilsson, E., additional, Blay-Carreras, E., additional, and Gioli, B., additional

Published

2014

8. Role of the residual layer and large-scale subsidence on the development and evolution of the convective boundary layer

Author

Blay-Carreras, E., primary, Pino, D., additional, Vilà-Guerau de Arellano, J., additional, van de Boer, A., additional, De Coster, O., additional, Darbieu, C., additional, Hartogensis, O., additional, Lohou, F., additional, Lothon, M., additional, and Pietersen, H., additional

Published

2014

9. The BLLAST field experiment: Boundary-Layer Late Afternoon and Sunset Turbulence

Author

Lothon, M., primary, Lohou, F., additional, Pino, D., additional, Couvreux, F., additional, Pardyjak, E. R., additional, Reuder, J., additional, Vilà-Guerau de Arellano, J., additional, Durand, P., additional, Hartogensis, O., additional, Legain, D., additional, Augustin, P., additional, Gioli, B., additional, Faloona, I., additional, Yagüe, C., additional, Alexander, D. C., additional, Angevine, W. M., additional, Bargain, E., additional, Barrié, J., additional, Bazile, E., additional, Bezombes, Y., additional, Blay-Carreras, E., additional, van de Boer, A., additional, Boichard, J. L., additional, Bourdon, A., additional, Butet, A., additional, Campistron, B., additional, de Coster, O., additional, Cuxart, J., additional, Dabas, A., additional, Darbieu, C., additional, Deboudt, K., additional, Delbarre, H., additional, Derrien, S., additional, Flament, P., additional, Fourmentin, M., additional, Garai, A., additional, Gibert, F., additional, Graf, A., additional, Groebner, J., additional, Guichard, F., additional, Jimenez Cortes, M. A., additional, Jonassen, M., additional, van den Kroonenberg, A., additional, Lenschow, D. H., additional, Magliulo, V., additional, Martin, S., additional, Martinez, D., additional, Mastrorillo, L., additional, Moene, A. F., additional, Molinos, F., additional, Moulin, E., additional, Pietersen, H. P., additional, Piguet, B., additional, Pique, E., additional, Román-Cascón, C., additional, Rufin-Soler, C., additional, Saïd, F., additional, Sastre-Marugán, M., additional, Seity, Y., additional, Steeneveld, G. J., additional, Toscano, P., additional, Traullé, O., additional, Tzanos, D., additional, Wacker, S., additional, Wildmann, N., additional, and Zaldei, A., additional

Published

2014

10. Role of the residual layer and large-scale subsidence on the development and evolution of the convective boundary layer

Author

Blay-Carreras, E., primary, Pino, D., additional, Van de Boer, A., additional, De Coster, O., additional, Darbieu, C., additional, Hartogensis, O., additional, Lohou, F., additional, Lothon, M., additional, Pietersen, H., additional, and Vilà-Guerau de Arellano, J., additional

Published

2013

11. Turbulence Kinetic Energy budget during the afternoon transition - Part 1: Observed surface TKE budget and boundary layer description for 10 intensive observation period days.

Author

Nilsson, E., Lohou, F., Lothon, M., Pardyjak, E., Mahrt, L., and Darbieu, C.

Abstract

The decay of turbulence kinetic energy (TKE) and its budget in the afternoon period from mid-day until zero buoyancy flux at the surface is studied in a two-part paper by means of measurements from the Boundary Layer Late Afternoon and Sunset Turbulence (BLLAST) field campaign for 10 Intensive Observation Period days. Here, in Part 1, near-surface measurements from a small tower are used to estimate a TKE budget. The overall boundary layer characteristics and meso-scale situation at the site are also described based upon taller tower measurements, radiosoundings and remote sensing instrumentation. Analysis of the TKE budget during the afternoon transition reveals a variety of different surface layer dynamics in terms of TKE and TKE decay. This is largely attributed to variations in the 8m wind speed, which is responsible for different amounts of near-surface shear production on different afternoons and variations within some of the afternoon periods. The partitioning of near surface production into local dissipation and transport in neutral and unstably stratified conditions was investigated. Although variations exist both between and within afternoons, as a rule of thumb, our results suggest that about 50% of the near surface production of TKE is compensated by local dissipation near the surface, leaving about 50% available for transport. This result indicates that it is important to also consider TKE transport as a factor influencing the near-surface TKE decay rate, which in many earlier studies has mainly been linked with the production terms of TKE by buoyancy and wind shear. We also conclude that the TKE tendency is smaller than the other budget terms, indicating a quasi-stationary evolution of TKE in the afternoon transition. Even though the TKE tendency was observed to be small, a strong correlation to mean buoyancy production of -0.69 was found for the afternoon period. For comparison with previous results, the TKE budget terms are normalized with friction velocity and measurement height and discussed in the framework of Monin-Obukhov similarity theory. Empirically fitted expressions are presented. Alternatively, we also suggest a non-local parametrization of dissipation using a TKE-length scale model which takes into account the boundary layer depth in addition to distance above the ground. The non-local formulation is shown to give a better description of dissipation compared to a local parametrization. [ABSTRACT FROM AUTHOR]

Published

2015

12. Turbulence Kinetic Energy budget during the afternoon transition - Part 2: A simple TKE model.

Author

Nilsson, E., Lothon, M., Lohou, F., Pardyjak, E., Hartogensis, O., and Darbieu, C.

Abstract

A simple model for turbulence kinetic energy (TKE) and the TKE budget is presented for sheared convective atmospheric conditions based on observations from the Boundary Layer Late Afternoon and Sunset Turbulence (BLLAST) field campaign. It is based on an idealized mixed-layer approximation and a simplified near-surface TKE budget. In this model, the TKE is dependent on four budget terms (turbulent dissipation rate, buoyancy production, shear production and vertical transport of TKE) and only requires measurements of three input available (near-surface buoyancy flux, boundary layer depth and wind speed at one height in the surface layer). This simple model is shown to reproduce some of the observed variations between the different studied days in terms of near-surface TKE and its decay during the afternoon transition reasonably well. It is subsequently used to systematically study the effects of buoyancy and shear on TKE evolution using idealized constant and time-varying winds during the afternoon transition. From this, we conclude that many different TKE decay rates are possible under time-varying winds and that generalizing the decay with simple scaling laws for near-surface TKE of the form ta may be questionable. The model's errors result from the exclusion of processes such as elevated shear production and horizontal advection. The model also produces an overly rapid decay of shear production with height. However, the most influential budget terms governing near-surface TKE in the observed sheared convective boundary layers are included, while only second order factors are neglected. Comparison between modeled and averaged observed estimates of dissipation rate illustrate that the overall behavior of the model is often quite reasonable. Therefore, we use the model to discuss the low turbulence conditions that form first in the upper parts of the boundary layer during the afternoon transition and are only apparent later near the surface. This occurs as a consequence of the continuous decrease of near-surface buoyancy flux during the afternoon transition. This region of weak afternoon turbulence is hypothesized to be a "pre-residual layer," which is important in determining the onset conditions for the weak sporadic turbulence that occur in the residual layer once near-surface stratification has become stable. [ABSTRACT FROM AUTHOR]

Published

2015

13. Turbulence vertical structure of the boundary layer during the afternoon transition.

Author

Darbieu, C., Lohou, F., Lothon, M., de Arellano, J. Vilà-Guerau, Couvreux, F., Durand, P., Pino, D., Patton, E. G., Nilsson, E., Blay-Carreras, E., and Gioli, B.

Abstract

We investigate the decay of planetary boundary layer (PBL) turbulence in the afternoon, from the time the surface buoyancy flux starts to decrease until sunset. Dense observations of mean and turbulent parameters were acquired during the Boundary Layer Late Afternoon and Sunset Turbulence (BLLAST) field experiment by several meteorological surface stations, sounding balloons, radars, lidars, and two aircraft flying extensively during the afternoon transition. We analyzed a case study based on some of those observations and Large-Eddy Simulation (LES) data focusing on the turbulent vertical structure throughout the afternoon transition. The decay of turbulence is quantified through the temporal and vertical evolution of (1) the turbulence kinetic energy (TKE), (2) the characteristic length scales of turbulence, (3) the shape of the turbulence spectra. A spectral analysis of LES data, airborne and surface measurements is performed in order to (1) characterize the variation of the turbulent decay with height and (2) study the distribution of turbulence over eddy size. This study points out the LES ability to reproduce the turbulence evolution throughout the afternoon. LES and observations agree that the afternoon transition can be divided in two phases: (1) a first phase during which the TKE decays with a low rate, with no significant change in turbulence characteristics, (2) a second phase characterized by a larger TKE decay rate and a change spectral shape, implying an evolution of eddy size distribution and energy cascade from low to high wavenumber. The changes observed either on TKE decay (during the first phase) or on the vertical wind spectra shape (during the second phase of the afternoon transition) occur first in the upper region of the PBL. The higher within the PBL, the stronger the spectra shape changes. [ABSTRACT FROM AUTHOR]

Published

2014

14. Role of the residual layer and large-scale subsidence on the development and evolution of the convective boundary layer.

Author

Blay-Carreras, E., Pino, D., Van de Boer, A., De Coster, O., Darbieu, C., Hartogensis, O., Lohou, F., Lothon, M., Pietersen, H., and de Arellano, J. Vilà-Guerau

Abstract

Observations, mixed-layer theory and the Dutch Large-Eddy Simulation model (DALES) are used to analyze the dynamics of the boundary layer during an intensive operational period (1 July 2011) of the Boundary Layer Late Afternoon and Sunset Turbulence campaign. Continuous measurements made by remote sensing and in situ instruments in combination with radio soundings, and measurements done by remotely piloted airplane systems and two aircrafts probed the vertical structure and the temporal evolution of the boundary layer during the campaign. The initial vertical profiles of potential temperature, specific humidity and wind, and the temporal evolution of the surface heat and moisture fluxes prescribed in the numerical simulations are inspired by some of these observations. The research focuses on the role played by the residual layer during the morning transition and by the large-scale subsidence on the evolution of the boundary layer. By using DALES, we show the importance of the dynamics of the boundary layer during the previous night in the development of the boundary layer at the morning. DALES numerical experiments including the residual layer are capable to model the observed sudden increase of the boundary-layer depth during the morning transition and the subsequent evolution of the boundary layer. The simulation shows a large increase of the entrainment buoyancy heat flux when the residual layer is incorporated into the mixed layer. We also examine how the inclusion of the residual layer above a shallow convective boundary layer modifies the turbulent kinetic energy budget. Large-scale subsidence mainly acts when the boundary layer is fully developed and, for the studied day, it is necessary to be considered to reproduce the afternoon observations. Additionally, we investigate how carbon dioxide (CO2) mixing ratio stored the previous night in the residual layer plays a fundamental role in the evolution of the CO2 mixing ratio during the following day. [ABSTRACT FROM AUTHOR]

Published

2013