Observation of turbulent dispersion of artificially released SO2 puffs with UV cameras

In atmospheric tracer experiments, a substance is released into the turbulent atmospheric flow to study the dispersion parameters of the atmosphere. That can be done by observing the substance's concentration distribution downwind of the source. Past experiments have suffered from the fact that...

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Bibliographic Details
Published in:Atmospheric measurement techniques 2018-11, Vol.11 (11), p.6169-6188
Main Authors: Dinger, Anna Solvejg, Stebel, Kerstin, Cassiani, Massimo, Ardeshiri, Hamidreza, Cirilo Bernardo, Kylling, Arve, Soon-Young, Park, Pisso, Ignacio, Schmidbauer, Norbert, Wasseng, Jan, Stohl, Andreas
Format: Article
Language:English
Subjects:
Atmosphere
Atmospheric boundary layer
Atmospheric models
Boundary layers
Cameras
Case studies
Computational fluid dynamics
Covariance
Data
Datasets
Dispersion
Distribution
Eddy covariance
Evolution
Feasibility studies
Fluxes
Image reconstruction
Induction heating
Meandering
Modelling
Momentum
Observation times
Parameters
Plumes
Resolution
Scaling
Spatial discrimination
Spatial resolution
Stability
Sulfur
Sulfur dioxide
Sulphur
Sulphur dioxide
Temporal resolution
Time
Tracer experiments
Tracers
Turbulent flow
Ultraviolet radiation
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Summary:In atmospheric tracer experiments, a substance is released into the turbulent atmospheric flow to study the dispersion parameters of the atmosphere. That can be done by observing the substance's concentration distribution downwind of the source. Past experiments have suffered from the fact that observations were only made at a few discrete locations and/or at low time resolution. The Comtessa project (Camera Observation and Modelling of 4-D Tracer Dispersion in the Atmosphere) is the first attempt at using ultraviolet (UV) camera observations to sample the three-dimensional (3-D) concentration distribution in the atmospheric boundary layer at high spatial and temporal resolution. For this, during a three-week campaign in Norway in July 2017, sulfur dioxide (SO2), a nearly passive tracer, was artificially released in continuous plumes and nearly instantaneous puffs from a 9 m high tower. Column-integrated SO2 concentrations were observed with six UV SO2 cameras with sampling rates of several hertz and a spatial resolution of a few centimetres. The atmospheric flow was characterised by eddy covariance measurements of heat and momentum fluxes at the release mast and two additional towers. By measuring simultaneously with six UV cameras positioned in a half circle around the release point, we could collect a data set of spatially and temporally resolved tracer column densities from six different directions, allowing a tomographic reconstruction of the 3-D concentration field. However, due to unfavourable cloudy conditions on all measurement days and their restrictive effect on the SO2 camera technique, the presented data set is limited to case studies. In this paper, we present a feasibility study demonstrating that the turbulent dispersion parameters can be retrieved from images of artificially released puffs, although the presented data set does not allow for an in-depth analysis of the obtained parameters. The 3-D trajectories of the centre of mass of the puffs were reconstructed enabling both a direct determination of the centre of mass meandering and a scaling of the image pixel dimension to the position of the puff. The latter made it possible to retrieve the temporal evolution of the puff spread projected to the image plane. The puff spread is a direct measure of the relative dispersion process. Combining meandering and relative dispersion, the absolute dispersion could be retrieved. The turbulent dispersion in the vertical is then used to estimate the
ISSN:1867-1381
1867-8548
DOI:10.5194/amt-11-6169-2018