Your search keyword '"Ganzeveld, L."' showing total 5 results

1. In-Canopy Turbulence—State of the Art and Potential Improvements

Author

Theobald, M., Loubet, B., Ammann, C., Branislava, L., Chojnicki, B., Ganzeveld, L., Grosz, B., Kaasik, M., Noe, S., Olejnik, J., Rinne, J., Shapkalijevski, M., Simpson, D., Tchepel, O., Tuovinen, J.-P., Weidinger, T., Wichink Kruit, R., Massad, Raia-Silva, editor, and Loubet, Benjamin, editor

Published

2015

2. Characterization of a boreal convective boundary layer and its impact on atmospheric chemistry during HUMPPA-COPEC-2010.

Author

Ouwersloot, H. G., de Arellano, J. Vilà-Guerau, Nölscher, A. C., Krol, M. C., Ganzeveld, L. N., Breitenberger, C., Mammarella, I., Williams, J., and Lelieveld, J.

Subjects

CONVECTION (Meteorology), ATMOSPHERIC boundary layer, ATMOSPHERIC chemistry, TEMPERATURE effect, MOISTURE, PROTOTYPES, METEOROLOGICAL observations

Abstract

We studied the atmospheric boundary layer (ABL) dynamics and the impact on atmospheric chemistry during the HUMPPA-COPEC-2010 campaign. We used vertical profiles of potential temperature and specific moisture, obtained from 132 radio soundings, to determine the main boundary layer characteristics during the campaign. We propose a classification according to several main ABL prototypes. Further, we performed a case study of a single day, focusing on the convective boundary layer, to analyse the influence of the dynamics on the chemical evolution of the ABL. We used a mixed layer model, initialized and constrained by observations. In particular, we investigated the role of large scale atmospheric dynamics (subsidence and advection) on the ABL development and the evolution of chemical species concentrations. We find that, if the large scale forcings are taken into account, the ABL dynamics are represented satisfactorily. Subsequently, we studied the impact of mixing with a residual layer aloft during the morning transition on atmospheric chemistry. The time evolution of NOx and O3 concentrations, including morning peaks, can be explained and accurately simulated by incorporating the transition of the ABL dynamics from night to day. We demonstrate the importance of the ABL height evolution for the representation of atmospheric chemistry. Our findings underscore the need to couple the dynamics and chemistry at different spatial scales (from turbulence to mesoscale) in chemistry-transport models and in the interpretation of observational data. [ABSTRACT FROM AUTHOR]

Published

2012

3. Combined effects of surface conditions, boundary layer dynamics and chemistry on diurnal SOA evolution.

Author

Janssen, R. H. H., de Arellano, J. Vilà-Guerau, Ganzeveld, L. N., Kabat, P., Jimenez, J. L., Farmer, D. K., van Heerwaarden, C. C., and Mammarella, I.

Subjects

ATMOSPHERIC boundary layer, DIURNAL variations in meteorology, ATMOSPHERIC aerosols, ATMOSPHERIC chemistry, CASE studies, SURFACE energy, TROPOSPHERE

Abstract

We study the combined effects of land surface conditions, atmospheric boundary layer dynamics and chemistry on the diurnal evolution of biogenic secondary organic aerosol in the atmospheric boundary layer, using a model that contains the essentials of all these components. First, we evaluate the model for a case study in Hyytiälä, Finland, and find that it is able to satisfactorily reproduce the observed dynamics and gas-phase chemistry. We show that the exchange of organic aerosol between the free troposphere and the boundary layer (entrainment) must be taken into account in order to explain the observed diurnal cycle in organic aerosol (OA) concentration. An examination of the budgets of organic aerosol and terpene concentrations show that the former is dominated by entrainment, while the latter is mainly driven by emission and chemical transformation. We systematically investigate the role of the land surface, which governs both the surface energy balance partitioning and terpene emissions, and the large-scale atmospheric process of vertical subsidence. Entrainment is especially important for the dilution of organic aerosol concentrations under conditions of dry soils and low terpene emissions. Subsidence suppresses boundary layer growth while enhancing entrainment. Therefore, it influences the relationship between organic aerosol and terpene concentrations. Our findings indicate that the diurnal evolution of secondary organic aerosols (SOA) in the boundary layer is the result of coupled effects of the land surface, dynamics of the atmospheric boundary layer, chemistry, and free troposphere conditions. This has potentially some consequences for the design of both field campaigns and large-scale modeling studies. [ABSTRACT FROM AUTHOR]

Published

2012

4. On the segregation of chemical species in a clear boundary layer over heterogeneous land surfaces.

Author

Ouwersloot, H. G., de Arellano, J. Vilä-Guerau, van Heerwaarden, C. C., Ganzeveld, L. N., Krol, M. C., and Lelieveld, J.

Subjects

ATMOSPHERIC boundary layer, LARGE eddy simulation models, ATMOSPHERIC turbulence, ISOPRENE, NITRIC oxide, CHEMICAL reactions, PARAMETER estimation

Abstract

Using a Large-Eddy Simulation model, we have systematically studied the inability of boundary layer turbulence to efficiently mix reactive species. This creates regions where the species are accumulated in a correlated or anti-correlated way, thereby modifying the mean reactivity. We quantify this modification by the intensity of segregation, IS, and analyse the driving mechanisms: heterogeneity of the surface moisture and heat fluxes, various background wind patterns and non-uniform isoprene emissions. The heterogeneous surface conditions are characterized by cool and wet forested patches with high isoprene emissions, alternated with warm and dry patches that represents pasture with relatively low isoprene emissions. For typical conditions in the Amazon rain forest, applying homogeneous surface forcings and in the absence of free tropospheric NOx, the isoprene-OH reaction rate is altered by less than 10 %. This is substantially smaller than the previously assumed IS of 50% in recent large-scale model analyses of tropical rain forest chemistry. Spatial heterogeneous surface emissions enhance the segregation of species, leading to alterations of the chemical reaction rates up to 20 %. The intensities of segregation are enhanced when the background wind direction is parallel to the borders between the patches and reduced in the case of a perpendicular wind direction. The effects of segregation on trace gas concentrations vary per species. For the highly reactive OH, the differences in concentration averaged over the boundary layer are less than 2% compared to homogeneous surface conditions, while the isoprene concentration is increased by as much as 12% due to the reduced chemical reaction rates. These processes take place at the sub-grid scale of chemistry transport models and therefore need to be parameterized. [ABSTRACT FROM AUTHOR]

Published

2011

5. Water-side turbulence enhancement of ozone deposition to the ocean.

Author

Fairall, C. W., Helmig, D., Ganzeveld, L., and Hare, J.

Subjects

OCEAN-atmosphere interaction, ATMOSPHERIC ozone, GASES, ATMOSPHERIC boundary layer, TURBULENCE, METEOROLOGY

Abstract

A parameterization for the deposition velocity of an ocean-reactive atmospheric gas (such as ozone) is developed. The parameterization is based on integration of the turbulent-molecular transport equation (with a chemical source term) in the ocean. It extends previous work that only considered reactions within the oceanic molecular sublayer. The sensitivity of the ocean-side transport to reaction rate and wind forcing is examined. A more complicated case with a much more reactive thin surfactant layer is also considered. The full atmosphere-ocean deposition velocity is obtained by matching boundary conditions at the interface. For an assumed ocean reaction rate of 10³ s-1, the enhancement for ozone deposition by oceanic turbulence is found to be up to a factor of three for meteorological data obtained in a recent cruise off the East Coast of the U.S. [ABSTRACT FROM AUTHOR]

Published

2007