A combined laboratory and modeling study of the infrared extinction and visible light scattering properties of mineral dust aerosol

[1] Optical properties, including infrared (IR) extinction and visible light scattering of mineral dust aerosol, are measured experimentally and compared to modeling results using T-matrix theory. The work includes studies of complex, authentic field samples of Saharan sand, Iowa loess, and Arizona road dust (ARD). Particle size distributions and aerosol optical properties are measured simultaneously. These authentic dust samples are treated as external mixtures of mineral components. The mineral compositions for the Saharan sand and Iowa loess samples have been reported by Laskina et al. [2012], and the mineralogy for ARD is derived here using a similar method. T-matrix-based simulations, using measured particle size distributions and a priori particle shape models, are carried out for each mineral component of the authentic samples. The simulated optical properties for the complex dust mixtures are obtained by a weighted average of the properties of the mineral components, based on a given sample mineralogy. T-matrix simulations are then directly compared with the measured IR extinction spectra and visible light scattering phase function and linear polarization profiles for each sample. Generally good agreement between experiment and theory is obtained. Model simulations that account for differences in particle shape with mineralogy and include a broad range of eccentric spheroid shape parameters offer a significant improvement over more commonly applied models that ignore variations in particle shape with size or mineralogy and include only a moderate range of shape parameters.

[1]  A. Wiedensohler,et al.  Size distribution, mass concentration, chemical and mineralogical composition and derived optical parameters of the boundary layer aerosol at Tinfou, Morocco, during SAMUM 2006 , 2009 .

[2]  V. Grassian,et al.  Correlated IR spectroscopy and visible light scattering measurements of mineral dust aerosol , 2010 .

[3]  V. Masson,et al.  Satellite climatology of African dust transport in the Mediterranean atmosphere , 1998 .

[4]  M. Kahnert,et al.  Sensitivity of the shortwave radiative effect of dust on particle shape: Comparison of spheres and spheroids , 2012 .

[5]  Optical modeling of vesicular volcanic ash particles , 2011 .

[6]  T. Nousiainen,et al.  Comparison of measured single-scattering matrix of feldspar particles with T-matrix simulations using spheroids , 2003 .

[7]  C. Zender,et al.  Quantifying mineral dust mass budgets:Terminology, constraints, and current estimates , 2004 .

[8]  M. Kahnert,et al.  Modelling light scattering by mineral dust using spheroids : assessment of applicability , 2011 .

[9]  Zhaokai Meng,et al.  Single-scattering properties of tri-axial ellipsoidal mineral dust aerosols: A database for application to radiative transfer calculations , 2010 .

[10]  Oleg Dubovik,et al.  Non‐spherical aerosol retrieval method employing light scattering by spheroids , 2002 .

[11]  Karri Muinonen,et al.  Scattering of light by large Saharan dust particles in a modified ray optics approximation , 2003 .

[12]  P. Nadeau Relationships between the mean area, volume and thickness for dispersed particles of kaolinites and micaceous clays and their application to surface area and ion exchange properties , 1987, Clay Minerals.

[13]  Michael Garstang,et al.  Saharan dust in the Amazon Basin , 1992 .

[14]  Thomas Trautmann,et al.  Thermal IR radiative properties of mixed mineral dust and biomass aerosol during SAMUM-2 , 2011 .

[15]  Michael Kahnert,et al.  Reproducing the optical properties of fine desert dust aerosols using ensembles of simple model particles , 2004 .

[16]  A. Avila,et al.  Mineralogical composition of African dust delivered by red rains over northeastern Spain , 1997 .

[17]  J. Prospero,et al.  Saharan aerosols over the tropical North Atlantic — Mineralogy , 1980 .

[18]  Y. Balkanski,et al.  Modeling the mineralogy of atmospheric dust sources , 1999 .

[19]  Jost Heintzenberg,et al.  Shape of atmospheric mineral particles collected in three Chinese arid‐regions , 2001 .

[20]  D. T. Davidson Studies of the Clay Fraction of Southwestern Iowa Loess , 1953 .

[21]  W. Maenhaut,et al.  Elemental Composition of Mineral Aerosol Generated from Sudan Sahara Sand , 2001 .

[22]  O. Torres,et al.  ENVIRONMENTAL CHARACTERIZATION OF GLOBAL SOURCES OF ATMOSPHERIC SOIL DUST IDENTIFIED WITH THE NIMBUS 7 TOTAL OZONE MAPPING SPECTROMETER (TOMS) ABSORBING AEROSOL PRODUCT , 2002 .

[23]  Vicki H. Grassian,et al.  T‐matrix studies of aerosol particle shape effects on IR resonance spectral line profiles and comparison with an experiment , 2009 .

[24]  Martin Ebert,et al.  Recent progress in understanding physical and chemical properties of African and Asian mineral dust , 2011 .

[25]  Hester Volten,et al.  Scattering matrices of mineral aerosol particles at 441.6 nm and 632.8 nm , 2001 .

[26]  J. Prospero,et al.  Atmospheric transport of soil dust from Africa to South America , 1981, Nature.

[27]  R. H. Bray,et al.  The Mica in Argillaceous Sediments , 1937 .

[28]  J. Prospero Long‐term measurements of the transport of African mineral dust to the southeastern United States: Implications for regional air quality , 1999 .

[29]  Inez Y. Fung,et al.  Inferring dust composition from wavelength‐dependent absorption in Aerosol Robotic Network (AERONET) data , 2006 .

[30]  Timo Nousiainen,et al.  Optical modeling of mineral dust particles: A review , 2009 .

[31]  T. Posch,et al.  Carbonates in Space: The Challenge of Low-Temperature Data , 2007, 0706.3963.

[32]  Paul H. Nadeau THE PHYSICAL DIMENSIONS OF FUNDAMENTAL CLAY PARTICLES , 1985 .

[33]  M. Sébert,et al.  Mineral aerosols and source identification , 1987 .

[34]  C. Gautier,et al.  Investigations of the March 2006 African dust storm using ground-based column-integrated high spectral resolution infrared (8–13 μm) and visible aerosol optical thickness measurements: 2. Mineral aerosol mixture analyses , 2009 .

[35]  V. Grassian,et al.  Coupled infrared extinction and size distribution measurements for several clay components of mineral dust aerosol , 2008 .

[36]  V. Grassian,et al.  Simultaneous measurement of light-scattering properties and particle size distribution for aerosols : Application to ammonium sulfate and quartz aerosol particles , 2007 .

[37]  M. A. Khashan,et al.  Dispersion of the optical constants of quartz and polymethyl methacrylate glasses in a wide spectral range: 0.2–3 μm , 2001 .

[38]  R. Stognienko,et al.  III. The role of aluminium in circumstellar amorphous silicates , 1998 .

[39]  Jean-François Léon,et al.  Application of spheroid models to account for aerosol particle nonsphericity in remote sensing of desert dust , 2006 .

[40]  Cyril Moulin,et al.  Understanding the long‐term variability of African dust transport across the Atlantic as recorded in both Barbados surface concentrations and large‐scale Total Ozone Mapping Spectrometer (TOMS) optical thickness , 2005 .

[41]  Larry D. Travis,et al.  Capabilities and limitations of a current FORTRAN implementation of the T-matrix method for randomly oriented, rotationally symmetric scatterers , 1998 .

[42]  David D. Turner,et al.  Ground‐based infrared retrievals of optical depth, effective radius, and composition of airborne mineral dust above the Sahel , 2008 .

[43]  E. Ganor The frequency of Saharan dust episodes over Tel Aviv, Israel , 1994 .

[44]  V. Grassian,et al.  Infrared extinction spectra of mineral dust aerosol: Single components and complex mixtures , 2012 .

[45]  Olga V. Kalashnikova,et al.  Ability of multiangle remote sensing observations to identify and distinguish mineral dust types : Optical models and retrievals of optically thick plumes : Quantifying the radiative and biogeochemical impacts of mineral dust , 2005 .

[46]  Timo Nousiainen,et al.  Spherical and spheroidal model particles as an error source in aerosol climate forcing and radiance computations: A case study for feldspar aerosols , 2005 .

[47]  V. Grassian,et al.  A Newly Designed and Constructed Instrument for Coupled Infrared Extinction and Size Distribution Measurements of Aerosols , 2007 .

[48]  M. Querry,et al.  Optical constants of minerals and other materials from the millimeter to the ultraviolet , 1987 .

[49]  Beat Schmid,et al.  Comparison of methods for deriving aerosol asymmetry parameter , 2006 .

[50]  Ping Yang,et al.  Modeling optical properties of mineral aerosol particles by using nonsymmetric hexahedra. , 2010, Applied optics.

[51]  Y. Balkanski,et al.  Sensitivity of direct radiative forcing by mineral dust to particle characteristics , 2009 .

[52]  T. Nousiainen,et al.  Light scattering by large Saharan dust particles: Comparison of modeling and experimental data for two samples , 2011 .

[53]  O. Toon,et al.  Infrared characterization of water uptake by low‐temperature Na‐montmorillonite: Implications for Earth and Mars , 2005 .

[54]  V. Grassian,et al.  Evidence for particle size–shape correlations in the optical properties of silicate clay aerosol , 2012 .

[55]  A. Uchiyama,et al.  Shape modeling of mineral dust particles for light-scattering calculations using the spatial Poisson-Voronoi tessellation , 2010 .

[56]  J. Hovenier,et al.  Scattering matrix of quartz aerosols: comparison and synthesis of laboratory and Lorenz–Mie results , 2003 .

[57]  V. Freudenthaler,et al.  Long-range transport of Saharan dust to northern Europe : The 11-16 October 2001 outbreak observed with EARLINET , 2003 .

[58]  Irina N. Sokolik,et al.  Incorporation of mineralogical composition into models of the radiative properties of mineral aerosol from UV to IR wavelengths , 1999 .

[59]  Michel Legrand,et al.  Mineralogy of Saharan dust transported over northwestern tropical Atlantic Ocean in relation to source regions , 2002 .

[60]  Ping Yang,et al.  Single-scattering properties of triaxial ellipsoidal particles for a size parameter range from the Rayleigh to geometric-optics regimes. , 2009, Applied optics.

[61]  Hester Volten,et al.  Aerosol retrievals from AVHRR radiances: effects of particle nonsphericity and absorption and an updated long-term global climatology of aerosol properties , 2003 .

[62]  T. Gill,et al.  Long‐range transport of North African dust to the eastern United States , 1997 .

[63]  J. Niemi,et al.  Single‐scattering modeling of thin, birefringent mineral‐dust flakes using the discrete‐dipole approximation , 2009 .

[64]  Masaru Chiba,et al.  A numerical study of the contributions of dust source regions to the global dust budget , 2006 .

[65]  M. Mishchenko,et al.  T-matrix theory of electromagnetic scattering by particles and its applications: a comprehensive reference database , 2004 .

[66]  V. Grassian,et al.  Visible light scattering study at 470, 550, and 660 nm of components of mineral dust aerosol: Hematite and goethite , 2011 .

[67]  V. Grassian,et al.  A laboratory investigation of light scattering from representative components of mineral dust aerosol at a wavelength of 550 nm , 2008 .

[68]  P. Weidler,et al.  Change of the refractive index of illite particles by reduction of the Fe content of the octahedral sheet , 2008 .

[69]  A. Laskin,et al.  Heterogeneous chemistry of individual mineral dust particles from different dust source regions: the importance of particle mineralogy , 2004 .

[70]  M. Mishchenko,et al.  Modeling phase functions for dustlike tropospheric aerosols using a shape mixture of randomly oriented polydisperse spheroids , 1997 .

[71]  M. Kahnert,et al.  Can particle shape information be retrieved from light-scattering observations using spheroidal model particles? , 2011 .

[72]  V. Grassian,et al.  Coupled infrared extinction spectra and size distribution measurements for several non-clay components of mineral dust aerosol (quartz, calcite, and dolomite) , 2008 .

[73]  N. Mahowald,et al.  Sensitivity study of meteorological parameters on mineral aerosol mobilization, transport, and distribution , 2003 .

[74]  Melissa D. Lane,et al.  Midinfrared optical constants of calcite and their relationship to particle size effects in thermal emission spectra of granular calcite , 1999 .

[75]  M. Schnaiter,et al.  Optical properties and mineralogical composition of different Saharan mineral dust samples: a laboratory study , 2006 .

[76]  V. M. Zolotarev,et al.  Study of quartz glass by differential fourier transform IR reflection spectroscopy: Bulk and surface properties , 2009 .

[77]  M. Mishchenko,et al.  Efficient finite-difference time-domain scheme for light scattering by dielectric particles: application to aerosols. , 2000, Applied optics.

[78]  Hester Volten,et al.  Scattering matrix of large Saharan dust particles: Experiments and computations , 2007 .

[79]  Timo Nousiainen,et al.  Light scattering by small feldspar particles simulated using the Gaussian random sphere geometry , 2006 .

[80]  S. Nickovic,et al.  Modeling wind-blown desert dust in the southwestern United States for public health warning: A case study , 2005 .

[81]  B. Meland An investigation into particle shape effects on the light scattering properties of mineral dust aerosol , 2011 .

[82]  Timo Nousiainen,et al.  Light scattering modeling of small feldspar aerosol particles using polyhedral prisms and spheroids , 2006 .