Abstract
Abstract. Knowledge of the composition of atmospheric aerosols is important for reducing uncertainty in climate assessment. In this study, an improved algorithm is developed for the retrieval of atmospheric columnar aerosol components from optical remote sensing data. This is achieved by using the complex refractive index (CRI) of a multicomponent liquid system in the forward model and minimizing the differences with the observations. The aerosol components in this algorithm comprise five species, combining eight subcomponents including black carbon (BC), water-soluble organic matter (WSOM) and water-insoluble organic matter (WIOM), ammonium nitrate (AN), sodium chloride (SC), dust-like content (DU), and aerosol water content in the fine and coarse modes (AWf and AWc). The calculation of the CRI in the multicomponent liquid system allows for the separation of the water-soluble components (AN, WSOM and AWf) in the fine mode and SC and AWc in the coarse mode. The uncertainty in the retrieval results is analyzed based on the simulation of typical models, showing that the complex refractive index obtained from instantaneous optical–physical inversion compares well with that obtained from chemical estimation. The algorithm was used to retrieve the columnar aerosol components over China using the ground-based remote sensing measurements from the Sun–sky radiometer Observation NETwork (SONET) in the period from 2010 to 2016. The results were used to analyze the regional distribution and interannual variation. The analysis shows that the atmospheric columnar DU component is dominant in the northern region of China, whereas the AW is higher in the southern coastal region. The SC component retrieved over the desert in northwest China originates from a paleomarine source. The AN significantly decreased from 2011 to 2016, by 21.9 mg m−2, which is inseparable from China's environmental control policies.
Highlights
Atmospheric aerosol consists of a suspension of solid and/or liquid particles in the air
The aerosol component classification includes five principal species. Three of these components are further subdivided; i.e., organic matter is subdivided into water-soluble organic matter (WSOM) and water-insoluble organic matter (WIOM); inorganic salt consists of ammonium nitrate (AN) in the fine mode and sodium chloride (SC) in the coarse mode, and aerosol water content is the water content in the fine and in the coarse mode
The accurate measurement of atmospheric aerosol components plays an important role in reducing uncertainty in climate assessment
Summary
Atmospheric aerosol consists of a suspension of solid and/or liquid particles in the air. The chemical composition and mixing state of the aerosol particles affect their optical characteristics, which in turn influence the energy budget of the Earth– atmosphere system and climate (Boucher et al, 2013). Many methods are used including online analysis in the field, sample analysis in the laboratory and remote sensing estimation. Because of fast observation and low cost, the application of remote sensing techniques to estimate aerosol composition has developed rapidly since 2000. Satheesh and Srinivasan (2002), Satheesh et al (1999, 2002), and Satheesh and Krishna (2005) established an algorithm for the inversion of aerosol components from remote sensing data based on the hypothesis of external mixing and assuming fixed size distributions for each component. Internal-mixing hypotheses are widely used and multiple approaches have been developed
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