Limitation
of the Use of the Absorption Angstrom Exponent
for Source Apportionment of Equivalent Black Carbon: a Case Study
from the North West Indo-Gangetic Plain
posted on 2016-01-19, 00:00authored bySaryu Garg, Boggarapu
Praphulla Chandra, Vinayak Sinha, Roland Sarda-Esteve, Valerie Gros, Baerbel Sinha
Angstrom
exponent measurements of equivalent black carbon (BCeq)
have recently been introduced as a novel tool to apportion
the contribution of biomass burning sources to the BCeq mass. The BCeq is the mass of ideal BC with defined optical
properties that, upon deposition on the aethalometer filter tape,
would cause equal optical attenuation of light to the actual PM2.5 aerosol deposited. The BCeq mass hence is identical
to the mass of the total light-absorbing carbon deposited on the filter
tape. Here, we use simultaneously collected data from a seven-wavelength
aethalometer and a high-sensitivity proton-transfer reaction mass
spectrometer installed at a suburban site in Mohali (Punjab), India,
to identify a number of biomass combustion plumes. The identified
types of biomass combustion include paddy- and wheat-residue burning,
leaf litter, and garbage burning. Traffic plumes were selected for
comparison. We find that the combustion efficiency, rather than the
fuel used, determines αabs, and consequently, the
αabs can be ∼1 for flaming biomass combustion
and >1 for older vehicles that operate with poorly optimized engines.
Thus, the absorption angstrom exponent is not representative of the
fuel used and, therefore, cannot be used as a generic tracer to constrain
source contributions.