Brown and black carbon in Beijing aerosol: Implications for the effects of brown coating on light absorption by black carbon
Autor: | Guenter Engling, Rodney J. Weber, Zhen-yu Du, Yuan Cheng, Shu-ping Dong, Jiumeng Liu, Kebin He |
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Rok vydání: | 2017 |
Předmět: |
Total organic carbon
Environmental Engineering 010504 meteorology & atmospheric sciences Absorption spectroscopy Single-scattering albedo Chemistry Analytical chemistry Carbon black 010501 environmental sciences Particulates 01 natural sciences Pollution Aerosol chemistry.chemical_compound Environmental Chemistry Methanol Absorption (electromagnetic radiation) Waste Management and Disposal 0105 earth and related environmental sciences |
Zdroj: | The Science of the total environment. |
ISSN: | 1879-1026 |
Popis: | Brown carbon (BrC) is increasingly included in climate models as an emerging category of particulate organic compounds that can absorb solar radiation efficiently at specific wavelengths. Water-soluble organic carbon (WSOC) has been commonly used as a surrogate for BrC; however, it only represents a limited fraction of total organic carbon (OC) mass, which could be as low as about 20% in urban atmosphere. Using methanol as the extraction solvent, up to approximately 90% of the OC in Beijing aerosol was isolated and measured for absorption spectra over the ultraviolet-to-visible wavelength range. Compared to methanol-soluble OC (MSOC), WSOC underestimated BrC absorption by about 50% at 365nm. The mass absorption efficiencies measured for BrC in Beijing aerosol were converted to the imaginary refractive indices of BrC and subsequently used to compute BrC coating-induced enhancement of light absorption (Eabs) by black carbon. Eabs attributed to lensing was reduced in the case of BrC coating relative to that caused by purely-scattering coating. However, this reduction was overwhelmed by the effect of BrC shell absorption, indicating that the overall effect of BrC coating was an increase in Eabs. Methanol extraction significantly reduced charring of OC during thermal-optical analysis, leading to a large increase in the measured elemental carbon (EC) mass and an apparent improvement in the consistency of EC measurements by different thermal-optical methods. |
Databáze: | OpenAIRE |
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