Investigation of fine and coarse aerosol contributions to the total aerosol light scattering: Shape effects and concentration profiling by Raman lidar measurements
详细信息 查看全文
- 作者:Arturo Quirantesa ; aquiran@ugr.es ; Francisco J. Olmoa ; b ; fjolmo@ugr.es ; Hassan Lyamania ; b ; Antonio Valenzuelaa ; b ; Lucas Alados-Arboledasa ; b
- 关键词:Nonspherical particles ; Dust properties ; T-matrix ; ALFA database ; AERONET
- 刊名:Journal of Quantitative Spectroscopy and Radiative Transfer
- 出版年:2012
- 出版时间:December, 2012
- 年:2012
- 卷:113
- 期:18
- 页码:2593-2600
- 全文大小:468 K
文摘
Remote sensing techniques, such as sun-photometry (columnar integrated aerosol parameters) and Raman lidar (profile aerosol parameters), are used in inversion models to yield information about particle size distribution (PSD), concentration, and average refractive index (RI). Ground-based AERONET network uses sun-photometric measurements to retrieve columnar effective particle size distribution and refractive index values, as well as other radiative properties such as absorption optical depth, albedo, and asymmetry parameter, which do not have a strong dependence on particle shape. Raman lidar measurements, on the other hand, yield shape-dependent quantities like particle depolarization, backscattering and lidar ratio at several wavelengths. In order to evaluate what light scattering parameters can be used to infer information regarding particle shape and concentration, a set of computer simulations was carried out. AERONET-inverted particle data (PSD, RI, concentration) have been used as input. Simulated data are obtained from ALFA, a light-scattering database, using the kernel approximation scheme. As expected, the effect of fine mode particle shape on near-infrared (1064 nm) was found to be negligible; on the other hand, even a small amount of nonsphericity in small particles has a marked effect on depolarization ratio values. Data from a 2007 lidar campaign were then used to evaluate the validity of our approach on a real measurement campaign. Results show that our method can yield some information about layer profiling, such as the concentration of fine mode particles. Such information comes not as a best-fit solution but in the form of a compatible set of possible solutions, which could be narrowed by the use of closure relations.