Lunar dust characterization by polarimetric signature

Richard, Denis; Davis, Sanford S.

doi:10.1051/0004-6361:20079108

Cited by 5 publications

(4 citation statements)

References 21 publications

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“…We generate synthetic BC aggregates by aggregation of monomers in random walk (Richard and Davis, 2008;Richard et al, 2011). The synthetic BC aggregates are characterized by a volume equivalent radius (a eff also defined as the radius of a sphere containing all the volume of the particle) between 82 and 144 nm, a constant monomer diameter of 40 nm and an open-chain-like structure.…”

Section: Black Carbon Aggregatesmentioning

confidence: 99%

Perturbations of the optical properties of mineral dust particles by mixing with black carbon: a numerical simulation study

et al. 2015

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Abstract. Field observations show that individual aerosol particles are a complex mixture of a wide variety of species, reflecting different sources and physico-chemical transformations. The impacts of individual aerosol morphology and mixing characteristics on the Earth system are not yet fully understood. Here we present a sensitivity study on climaterelevant aerosols optical properties to various approximations. Based on aerosol samples collected in various geographical locations, we have observationally constrained size, morphology and mixing, and accordingly simulated, using the discrete dipole approximation model (DDSCAT), optical properties of three aerosols types: (1) bare black carbon (BC) aggregates, (2) bare mineral dust, and (3) an internal mixture of a BC aggregate laying on top of a mineral dust particle, also referred to as polluted dust.DDSCAT predicts optical properties and their spectral dependence consistently with observations for all the studied cases. Predicted values of mass absorption, scattering and extinction coefficients (MAC, MSC, MEC) for bare BC show a weak dependence on the BC aggregate size, while the asymmetry parameter (g) shows the opposite behavior. The simulated optical properties of bare mineral dust present a large variability depending on the modeled dust shape, confirming the limited range of applicability of spheroids over different types and size of mineral dust aerosols, in agreement with previous modeling studies. The polluted dust cases show a strong decrease in MAC values with the increase in dust particle size (for the same BC size) and an increase of the single scattering albedo (SSA). Furthermore, particles with a radius between 180 and 300 nm are characterized by a decrease in SSA values compared to bare dust, in agreement with field observations. This paper demonstrates that observationally constrained DDSCAT simulations allow one to better understand the variability of the measured aerosol optical properties in ambient air and to define benchmark biases due to different approximations in aerosol parametrization.

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Section: Black Carbon Aggregatesmentioning

confidence: 99%

Perturbations of the optical properties of mineral dust particles by mixing with black carbon: a numerical simulation study

et al. 2015

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“…This report does not deal extensively with the problem of lunar regolith and resulting dust 9,10 within the cabin. However, aerosols and their health risks have been studied due to terrestrial health concerns [11][12][13] and the presence of in-cabin aerosolized lunar regolith only exacerbates these risks.…”

Section: Initial Guidance From Altair Lunar Landermentioning

confidence: 99%

“…[14][15][16] The physiological implications for adverse effects, based on such easy access to the walls of astronaut alveoli, not to mention other threats to health and operations, deserves considerable attention. In any case, in order to detect and characterize aerosols, there are certainly charging/electrostatic techniques 12 as well as optical scattering techniques [17][18][19][20] , including analysis of polarization 10 , that seem appropriate and can monitor aerosols particles down to 0.1-µm diameter. Additionally, aerosol particles have been studied via single-particle mass spectroscopy [21][22][23] .…”

Section: Initial Guidance From Altair Lunar Landermentioning

confidence: 99%

Sensor systems for the Altair Lunar Lander:

Mariella¹

2009

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“…An accurate parametrization of aerosol optical properties due to variability in morphology and mixing with other aerosol compounds is crucial for a number of disciplines involving not only radiative forcing analysis and global and regional aerosol modeling (Samset et al, 2013;Kahnert, 2010b) but also aerosol-cloud interactions, visibility and precipitation forecasts (Lau and Kim, 2006) and, furthermore, remote sensing of atmosphere and ocean color (Russell and Heintzenburg, 2000;Durkee et al, 2000;Yoshida et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Perturbations of the optical properties of mineral dust particles by mixing with black carbon: a numerical simulation study

Scarnato¹,

China²,

Nielsen³

et al. 2015

Preprint

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Abstract. Field observations show that individual aerosol particles are a complex mixture of a wide variety of species, reflecting different sources and physico-chemical transformations. The impacts of individual aerosol morphology and mixing characteristics on the Earth system are not yet fully understood. Here we present a sensitivity study on climate relevant aerosols' optical properties to various approximations. Based on aerosol samples collected in various geographical locations, we have observationally constrained size, morphology and mixing, and accordingly simulated, using the discrete dipole approximation model (DDSCAT), optical properties of 3 aerosols types: (1) bare black carbon (BC) aggregates, (2) bare mineral dust, and (3) an internal mixture of a BC aggregate laying on top of a mineral dust particle, also referred as polluted dust. DDSCAT predicts optical properties and their spectral dependence consistently with observations for all the studied cases. Predicted values of mass absorption, scattering and extinction coefficients (MAC, MSC, MEC) for bare BC show a weak dependence on the BC aggregate size, while the asymmetry parameter (g) shows the opposites. The simulated optical properties of bare mineral dust present a large variability depending on the modeled dust shape, confirming the limited range of applicability of spheroids over different types and size of mineral dust aerosols, in agreement with previous modeling studies. The polluted dust cases show a strong decrease in MAC values with the increase in dust particle size (for the same BC size), while an increase of the single scattering albedo (SSA). Further, polluted dust particles with radius between 180–300 nm are characterized by a decrease in SSA values compared to bare dust, in agreement with field observations. This paper demonstrates that observationally constrained DDSCAT simulations allow to better understand the variability of the measured aerosol optical properties in ambient air, and to define benchmarks biases due to different approximations in aerosol parametrization.

show abstract

Lunar dust characterization by polarimetric signature

Cited by 5 publications

References 21 publications

Perturbations of the optical properties of mineral dust particles by mixing with black carbon: a numerical simulation study

Perturbations of the optical properties of mineral dust particles by mixing with black carbon: a numerical simulation study

Sensor systems for the Altair Lunar Lander:

Perturbations of the optical properties of mineral dust particles by mixing with black carbon: a numerical simulation study

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