Retrieval of Aerosol Physical and Chemical Properties from Mid-Infrared Extinction Spectra

A.Y. ZASETSKY; M.E. EARLE; B. COSIC; R. SCHIWON; I.A. GRISHIN; R. MCPHAIL; R.G. PANCESCU; J.J. NAJERA; A.F. KHALIZOV; K.B. COOK; J.J. SLOAN

JOURNAL OF QUANTITATIVE SPECTROSCOPY AND RADIATIVE TRANSFER

PERGAMON-ELSEVIER SCIENCE LTD

Lugar: Amsterdam; Año: 2007 vol. 107 p. 294 - 305

0022-4073

We report several results that validate the accuracy of a retrieval method for the determination of a number of aerosol particle properties from their mid infrared (600?6000 cm1 ) extinction spectra. These properties include the number density, chemical composition, phase, size distribution, and to some extent, shape. The approach is based on information obtained in laboratory studies of micron-sized particles using the aerosol flow tube (AFT) technique. We report here experiments in which our method is used to measure a variety of aerosols including SiO2 micro-spheres as well as solid NaCl, (NH4)2SO4, ice and liquid water particles. The uncertainties in the retrieved aerosol properties associated with the particle shapes (spheres, spheroids, cylinders, hexagonal and rectangular prisms) as well as the effect of variations in the spectral range were evaluated. To assess the accuracy of the retrieved size distributions and particle shapes, the properties calculated from infrared spectra were compared with corresponding properties determined using alternative methods. We used scanning electron microscopy (SEM) for solid (NH4)2SO4 and NaCl aerosols and direct particle imaging with an optical microscope assembly for liquid water aerosols. On the basis of the validation results, we discuss the boundaries of applicability of the most popular spectral model, single scattering by spherical, homogeneous aerosol particles.