Radiative impact of an extreme Arctic biomass-burning event

The aim of the presented study was to investigate the impact on the radiation budget of a biomass-burning plume, transported from Alaska to the High Arctic region of Ny-Ålesund, Svalbard, in early July 2015. Since the mean aerosol optical depth increased by the factor of 10 above the average summer...

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Bibliographic Details
Published in:Atmospheric chemistry and physics 2018-06, Vol.18 (12), p.8829-8848
Main Authors: Lisok, Justyna, Rozwadowska, Anna, Pedersen, Jesper G, Markowicz, Krzysztof M, Ritter, Christoph, Kaminski, Jacek W, Struzewska, Joanna, Mazzola, Mauro, Udisti, Roberto, Becagli, Silvia, Gorecka, Izabela
Format: Article
Language:English
Subjects:
Aerodynamics
Aerosol optical depth
Aerosols
Albedo
Albedo (solar)
Approximation
Arctic zone
Atmosphere
Atmospheric models
Atmospheric radiation
Biomass
Biomass burning
Biomass burning plumes
Burning
Chemical properties
Combustion
Computer simulation
Environmental aspects
Environmental impact analysis
Genetic transformation
Heating
Heating rate
Hygroscopicity
Kinetic energy
Meteorological satellites
Methods
Optical analysis
Organic chemistry
Profiles
Radiation
Radiation budget
Radiative forcing
Radiative transfer
Radiative transfer models
Radiometers
Remote sensing
Satellites
Sky
Smoke
Turbulent kinetic energy
Vertical mixing
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Summary:The aim of the presented study was to investigate the impact on the radiation budget of a biomass-burning plume, transported from Alaska to the High Arctic region of Ny-Ålesund, Svalbard, in early July 2015. Since the mean aerosol optical depth increased by the factor of 10 above the average summer background values, this large aerosol load event is considered particularly exceptional in the last 25 years. In situ data with hygroscopic growth equations, as well as remote sensing measurements as inputs to radiative transfer models, were used, in order to estimate biases associated with (i) hygroscopicity, (ii) variability of single-scattering albedo profiles, and (iii) plane-parallel closure of the modelled atmosphere. A chemical weather model with satellite-derived biomass-burning emissions was applied to interpret the transport and transformation pathways. The provided MODTRAN radiative transfer model (RTM) simulations for the smoke event (14:00 9 July–11:30 11 July) resulted in a mean aerosol direct radiative forcing at the levels of −78.9 and −47.0 W m−2 at the surface and at the top of the atmosphere, respectively, for the mean value of aerosol optical depth equal to 0.64 at 550 nm. This corresponded to the average clear-sky direct radiative forcing of −43.3 W m−2, estimated by radiometer and model simulations at the surface. Ultimately, uncertainty associated with the plane-parallel atmosphere approximation altered results by about 2 W m−2. Furthermore, model-derived aerosol direct radiative forcing efficiency reached on average −126 W m-2/τ550 and −71 W m-2/τ550 at the surface and at the top of the atmosphere, respectively. The heating rate, estimated at up to 1.8 K day−1 inside the biomass-burning plume, implied vertical mixing with turbulent kinetic energy of 0.3 m2 s−2.
ISSN:1680-7324
1680-7316
1680-7324
DOI:10.5194/acp-18-8829-2018