Publication Date:
2019-06-11
Description:
Aerosol strongly affect the radiation balance, especially in the Arctic where climate change is significantly faster
compared to lower latitudes. The interaction between aerosol and radiation can be either direct (scattering and
absorption) or indirect (aerosol serving as cloud condensation nuclei and ice nucleating particles). Aerosol optical
properties can be provided by Lidar (Light Detection and Ranging) systems with high spatial and temporal
resolution. In this study, we utilize data from a ground-based Lidar system located in Ny-Ålesund, Spitsbergen
and an air-borne system installed onboard the research aircraft Polar5.
Our focus is on a rare event of elevated aerosol layers, which persistently appeared over two different parts of the
European Arctic during PAMARCMiP (Polar Air-borne Measurements and Arctic Regional Climate Model Simulation
Project) campaign in spring 2018. Results show that the detected layers exhibit similar optical properties,
namely aerosol backscatter coefficient, which is indicative of aerosol abundance and aerosol depolarization ratio,
which is an indicator of the aerosol shape. The main hypothesis is that although the existence of those layers is
rare, they impact on the radiation budget of the Arctic.
In the next steps of our research, we will investigate the occurrence of similar aerosol layers in the springtime of
previous years using long-term measurements from the Lidar system located in Ny-Ålesund. Our goal is to assess
the effect of different aerosol layers on the surface radiation budget and gain a better understanding of their role
in the amplified Arctic climate change, utilizing radiation measurements from the Ny-Ålesund BSRN (Baseline
Surface Radiation Network) station.
Repository Name:
EPIC Alfred Wegener Institut
Type:
Conference
,
notRev
Format:
application/pdf
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