Radiative forcing over the Arctic of aerosols from the August 2017 Canadian and Greenlandic wildfires

Extended and intense wildfires occurred in Northern Canada and, unexpectedly, on the Greenlandic West coast during summer 2017. The thick smoke plume emitted into the atmosphere was transported to the high Arctic, producing one of the largest impacts ever observed in the region. Evidence of Canadian...

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Bibliographic Details
Main Authors: Filippo Calì Quaglia, Daniela Meloni, Alcide Giorgio di Sarra, Tatiana Di Iorio, Virginia Ciardini, Domenico Pace, Giovanni Muscari, Silvia Becagli, Marco Cacciani, Ivan Ortega, James W. Hannigan, Brent N. Holben
Other Authors: CALÌ QUAGLIA, Filippo, Meloni, Daniela, Giorgio di Sarra, Alcide, Di Iorio, Tatiana, Ciardini, Virginia, Pace, Domenico, Muscari, Giovanni, Becagli, Silvia, Cacciani, Marco, Ortega, Ivan, Hannigan, James W., Holben, Brent N.
Format: Conference Object
Language:unknown
Published: EGU 2021
Subjects:
Online Access:https://hdl.handle.net/10278/5044870
https://doi.org/10.5194/EGUSPHERE-EGU21-7405
Description
Summary:Extended and intense wildfires occurred in Northern Canada and, unexpectedly, on the Greenlandic West coast during summer 2017. The thick smoke plume emitted into the atmosphere was transported to the high Arctic, producing one of the largest impacts ever observed in the region. Evidence of Canadian and Greenlandic wildfires was recorded at the Thule High Arctic Atmospheric Observatory (THAAO, 76.5°N, 68.8°W, www.thuleatmos-it.it) by a suite of instruments managed by ENEA, INGV, Univ. of Florence, and NCAR. Ground-based observations of the radiation budget have allowed quantification of the surface radiative forcing at THAAO. Excess biomass burning chemical tracers such as CO, HCN, H2CO, C2H6, and NH3 were measured in the air column above Thule starting from August 19 until August 23. The aerosol optical depth (AOD) reached a peak value of about 0.9 on August 21, while an enhancement of wildfire compounds was detected in PM10. The measured shortwave radiative forcing was -36.7 W/m2 at 78° solar zenith angle (SZA) for AOD=0.626. MODTRAN6.0 radiative transfer model (Berk et al., 2014) was used to estimate the aerosol radiative effect and the heating rate profiles at 78° SZA. Measured temperature profiles, integrated water vapour, surface albedo, spectral AOD and aerosol extinction profiles from CALIOP onboard CALIPSO were used as model input. The peak aerosol heating rate (+0.5 K/day) was reached within the aerosol layer between 8 and 12 km, while the maximum radiative effect (-45.4 W/m2) is found at 3 km, below the largest aerosol layer. The regional impact of the event that occurred on August 21 was investigated using a combination of atmospheric radiative transfer modelling with measurements of AOD and ground surface albedo from MODIS. The aerosol properties used in the radiative transfer model were constrained by in situ measurements from THAAO. Albedo data over the ocean have been obtained from Jin et al. (2004). Backward trajectories produced through HYSPLIT simulations (Stein et al., 2015) were also ...