Your search keyword '"Peter Zittel"' showing total 3 results

1. A New Method for the Determination of Area-Averaged Turbulent Surface Fluxes from Low-Level Flights Using Inverse Models

Author

Peter Zittel, Frank Beyrich, Jens Bange, Thomas Spieß, and Jörg Uhlenbrock

Subjects

Area-averaged turbulent fluxes, Atmospheric Science, Meteorology, Planetary boundary layer, Sensible heat, Atmospheric sciences, Convective Boundary Layer, Article, law.invention, Flux (metallurgy), LITFASS, law, Latent heat, ddc:551, Inverse models, ddc:6, Veröffentlichung der TU Braunschweig, ddc:62, Airborne measurements, Statistical errors, ddc:5, Turbulence, Heterogeneous surface, Scintillometer, Heat transfer, ddc:55, Environmental science, ddc:621

Abstract

The low-level flight method (LLF) has been combined with linear inverse models (IM) resulting in an LLF+IM method for the determination of area-averaged turbulent surface fluxes. With this combination, the vertical divergences of the turbulent latent and sensible heat fluxes were calculated from horizontal flights. The statistical errors of the derived turbulent surface fluxes were significantly reduced. The LLF+IM method was tested both in numerical and field experiments. Large-eddy simulations (LES) were performed to compare ‘true’ flux profiles with ‘measurements’ of simulated flights in an idealised convective boundary layer. Small differences between the ‘true’ and the ‘measured’ fluxes were found, but the vertical flux divergences were correctly calculated by the LLF+IM method. The LLF+IM method was then applied to data collected during two flights with the Helipod, a turbulence probe carried by a helicopter, and with the research aircraft Do 128 in the LITFASS-98 field campaign. The derived surface fluxes were compared with results from eddy-covariance surface stations and with large-aperture scintillometer data. The comparison showed that the LLF+IM method worked well for the sensible heat flux at 77 and 200 m flight levels, and also for the latent heat flux at the lowest level. The model quality control indicated failures for the latent heat flux at the 200 m level (and higher), which were probably due to large moisture fluctuations that could not be modelled using linear assumptions. Finally the LLF+IM method was applied to more than twenty low-level flights from the LITFASS-2003 experiment. Comparison with aggregated surface flux data revealed good agreement for the sensible heat flux but larger discrepancies and a higher statistical uncertainty for the latent heat flux

Published

2006

2. Area-averaged surface fluxes over the litfass region based on eddy-covariance measurements

Author

Jens Bange, Peter Zittel, Ulrich Weisensee, W.M.L. Meijninger, Frank Beyrich, Andreas Ludi, Matthias Mauder, Sven Huneke, Jens-Peter Leps, Thomas Foken, H. Lohse, and Dmitrii Mironov

Subjects

Meteorologie en Luchtkwaliteit, Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Meteorology and Air Quality, Planetary boundary layer, 0207 environmental engineering, Eddy covariance, hapex-mobilhy, 02 engineering and technology, Land cover, Sensible heat, turbulent fluxes, Atmospheric sciences, 01 natural sciences, law.invention, law, Latent heat, water-vapor fluxes, boreal forest, land-surfaces, Leaf area index, 020701 environmental engineering, Water content, 0105 earth and related environmental sciences, large-aperture, flevoland field experiment, boundary-layer, 15. Life on land, heterogeneous surface, Scintillometer, Environmental science, aircraft measurements

Abstract

Micrometeorological measurements (including eddy-covariance measurements of the surface fluxes of sensible and latent heat) were performed during the LITFASS-2003 experiment at 13 field sites over different types of land use (forest, lake, grassland, various agricultural crops) in a 20 × 20 km2 area around the Meteorological Observatory Lindenberg (MOL) of the German Meteorological Service (Deutscher Wetterdienst, DWD). Significant differences in the energy fluxes could be found between the major land surface types (forest, farmland, water), but also between the different agricultural crops (cereals, rape, maize). Flux ratios between the different surfaces changed during the course of the experiment as a result of increased water temperature of the lake, changing soil moisture, and of the vegetation development at the farmland sites. The measurements over grass performed at the boundary-layer field site Falkenberg of the MOL were shown to be quite representative for the farmland part of the area. Measurements from the 13 sites were composed into a time series of the area-averaged surface flux by taking into account the data quality of the single flux values from the different sites and the relative occurrence of each surface type in the area. Such composite fluxes could be determined for about 80% of the whole measurement time during the LITFASS-2003 experiment. Comparison of these aggregated surface fluxes with area-averaged fluxes from long-range scintillometer measurements and from airborne measurements showed good agreement.

Published

2006

3. STINHO Structure of turbulent transport under inhomogeneous surface conditions part 1: The micro- scale field experiment

Author

M. Schröter, Jens-Peter Leps, Jens Bange, Peter Zittel, Klaus Arnold, Siegfried Raasch, Thomas Spiess, Armin Raabe, Astrid Ziemann, Mathias Göckede, Thomas Foken, and Frank Beyrich

Subjects

Surface (mathematics), Atmospheric Science, Boundary layer, Scale (ratio), Field (physics), Meteorology, Turbulence, System of measurement, Airflow, Environmental science, Point (geometry), Mechanics, Physics::Atmospheric and Oceanic Physics

Abstract

A micrometeorological field experiment was performed within the frame of the STINHO-project (structure of turbulent transport under inhomogeneous conditions) at the boundary layer field site of the Meteorological Observatory Lindenberg of the German Meteorological Service (Deutscher Wetterdienst) in the summer of 2002 in order to investigate the interaction of thermally heterogeneous surfaces with the turbulent atmosphere. The intention was to compare conventional meteorological point and vertically integrated measurements with area-covering air flow observations and numerical simulations. To observe horizontally variable flow and temperature fields above a heterogeneous land surface, simultaneous acoustic methods (travel time tomography), optical observation methods (IR-camera and line-integrated scintillometer-measurements), as well as the airborne measurement system Helipod were used. The data set will be applied in future to validate large-eddy simulations adjusted to the area of investigation.

Published

2005