illumination independent aerosol optical properties
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Illumination Independent Aerosol Optical Properties. Extinction Scattering Absorption Volume scattering function (phase) Transmittance. Extinction =. The extinction coefficient is made up of particle and gas scattering and absorption: - PowerPoint PPT PresentationTRANSCRIPT
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Illumination Independent Aerosol Optical Properties
Extinction• Scattering• Absorption
Volume scattering function (phase) Transmittance
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The extinction coefficient is made up of
particle and gas scattering and absorption:
where s, a, g, and p refer to scattering, absorption, gases, and particles, respectively.
ext sg ag sp apb = b +b +b +b
Extinction =
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Components of Scattering and Extinction
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Animations of scattering and absorption
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One Approximation for Estimating bext
].[10
]SO
]SO
344
344
lacclacf)[SOIL](e +(RH)[OMC]f)(e +
]NO(RH)[NH)f(e +iated(RH)[Ammon)f(e
)[SOIL](e +(RH)[OMC]f)(e +
]NO(RH)[NH)f(e +iated(RH)[Ammon)f(e = b
soilcocmocmc
nncssc
soilfocmocmf
nnfssfext
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(D)d(D)n),m(QD4
=B iie2
o
iext,
(x)dx)x,,( fmE=B iie
-
iext,
where Ee is mass extinction efficiency, f i(x) is the aerosol mass distribution dm/dx of the ith species, x=ln[D/Do], and λ is the wavelength.
Extinction as Function of Size
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m =B iiiext,
(x)dx)x,,( fmE=iie
o
i
where
m =B i i
iext
and for multiple species
Externally Mixed Model
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Scattering Efficiency (Q)
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Single Particle Efficiency
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Particle Size Distribution
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Scattering Efficiency as Function of Size
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Carbon Extinction Efficiency
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Phase Function for Soil and Sulfate
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Phase Function for Carbon
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Forward and Backward Scattering
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Pollutant Species
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Primary vs. Secondary Particles and Gases (Pollutants)
Primary particles and gases are those emitted into the atmosphere directly from some source.
Secondary particles and gases are formed in the atmosphere by chemical reactions, by condensation growth, and/or by coagulation.
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Particle Size Distribution
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Sources of Primary Particles
Anthropogenic Wind Blown Dust
Roads, Over Grazing, Farming practices, Mining
Biomass BurningLand Clearing Practices
Emissions from fossil fuel combustionFly Ash Condensation of Hot Vapors
Naturally Occurring Wind Blown Dust
Deserts
Volcanoes Fires Plant Particles
(pollen)
Sea Salt Spray(NaCl)
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Sources of Primary Gases Important to Secondary Particle Formation
Compound Anthropogenic Naturally Occurring
SO2 Fossil-FuelSmelters
Oil Refining
Volcanoes
NOxFossil-Fuel Combustion
Mobil SourcesSoil Release (Fertilizer)
Soil ReleaseLightning
NH3 Farm Animals Wild AnimalsVegetation
Ocean Volatile
OrganicsMobile Sources Vegetation
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Hygroscopic Aerosols
Water uptake by particles in the atmosphere Aerosol particles grow and scatter more light Deliquescence - the RH value at which the
crystal begins to absorb water and becomes a solution droplet
Hysteresis - water is retained on the particle at RH values lower than predicted by equilibrium
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Growth of Sulfate
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Hygroscopic Growth of Particles
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Ammonium Sulfate D/Do Curves
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Two Measured f(RH) Curves and Theoretical Estimated
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F(rh) for Grand Canyon
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Estimated f(rh) for Sulfate and Organics
] [ ...... ] [ ] [ ) (2 1 ,Species Other a OMC a SULFATE a a RH bn o water scat
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Internally Mixed Aerosol
m B
m FM
i i
iext
i
i
however,
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Mass Removal Issues
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From previous equations, it is apparent that changes in visibility that correspond to changes in aerosol species concentrations can be expressed by forming the derivative τr/Ci, where Ci refers to the concentration of
particulate species i, and that this derivative will have terms containing the derivative bext/Ci. Therefore, define partial scattering
efficiency as:
Partial Scattering Efficiency
)C/b(=e etc ,ciextp j
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Extinction for External and Internal Mixture
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D/Do Curves for Partial Scattering Calculation
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Partial Scattering Efficiency for External and Internally Mixed Aerosols