Wildfire is one of the main sources of PM2.5 (particulate
matter with aerodynamic diameter < 2.5 μm) in the Alaskan
summer. The complexity in wildfire smokes, as well as limited coverage
of ground measurements, poses a big challenge to estimate surface
PM2.5 during wildfire season in Alaska. Here we aim at
proposing a quick and direct method to estimate surface PM2.5 over Alaska, especially in places exposed to strong wildfire events
with limited measurements. We compare the AOD–surface PM2.5 conversion factor (η = PM2.5/AOD; AOD,
aerosol optical depth) from the chemical transport model GEOS-Chem
(ηGC) and from observations (ηobs). We show that ηGC is biased high compared to ηobs under smoky conditions, largely because GEOS-Chem assigns
the majority of AOD (67%) within the planetary boundary layer (PBL)
when AOD > 1, inconsistent with satellite retrievals from CALIOP.
The overestimation in ηGC can be to some extent improved
by increasing the injection height of wildfire emissions. We constructed
a piecewise function for ηobs across different AOD
ranges based on VIIRS-SNPP AOD and PurpleAir surface PM2.5 measurements over Alaska in the 2019 summer and then applied it
on VIIRS AOD to derive daily surface PM2.5 over continental
Alaska in the 2021 and 2022 summers. The derived satellite PM2.5 shows a good agreement with corrected PurpleAir PM2.5 in Alaska during the 2021 and 2022 summers, suggesting
that aerosol vertical distribution likely represents the largest uncertainty
in converting AOD to surface PM2.5 concentrations. This
piecewise function, η′obs, shows the capability
of providing an observation-based, quick and direct estimation of
daily surface PM2.5 over the whole of Alaska during wildfires,
without running a 3-D model in real time.