Using spectral methods to obtain particle size information from optical data: applications to measurements from CARES 2010

Atkinson, Dean B.; Pekour, Mikhail; Chand, D.; Radney, James G.; Kolesar, Katheryn R.; Zhang, Qi; Setyan, Ari; O’Neill, Norman T.; Cappa, C. D.

doi:10.5194/acp-18-5499-2018

Cited by 4 publications

(6 citation statements)

References 43 publications

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“…Based on the in-situ measurements, the multispectral optical properties can not only provide information on particle size distribution [41] but also can calculate aerosol fine and coarse mode scattering and extinction coefficients by means of the extended spectral deconvolution algorithm (DSA+) methodology provided by Kaku et al [42]. To enhance subtle spectral features, derivative spectroscopy methods (see [43] for a recent review) on the basis of nth-order derivatives have been applied to the investigation of pharmacology, medical biology and satellite oceanography [44][45][46][47][48][49][50].…”

Section: Introductionmentioning

confidence: 99%

Spectral Derivatives of Optical Depth for Partitioning Aerosol Type and Loading

et al. 2021

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Quantifying aerosol compositions (e.g., type, loading) from remotely sensed measurements by spaceborne, suborbital and ground-based platforms is a challenging task. In this study, the first and second-order spectral derivatives of aerosol optical depth (AOD) with respect to wavelength are explored to determine the partitions of the major components of aerosols based on the spectral dependence of their particle optical size and complex refractive index. With theoretical simulations from the Second Simulation of a Satellite Signal in the Solar Spectrum (6S) model, AOD spectral derivatives are characterized for collective models of aerosol types, such as mineral dust (DS) particles, biomass-burning (BB) aerosols and anthropogenic pollutants (AP), as well as stretching out to the mixtures among them. Based on the intrinsic values from normalized spectral derivatives, referenced as the Normalized Derivative Aerosol Index (NDAI), a unique pattern is clearly exhibited for bounding the major aerosol components; in turn, fractions of the total AOD (fAOD) for major aerosol components can be extracted. The subtlety of this NDAI method is examined by using measurements of typical aerosol cases identified carefully by the ground-based Aerosol Robotic Network (AERONET) sun–sky spectroradiometer. The results may be highly practicable for quantifying fAOD among mixed-type aerosols by means of the normalized AOD spectral derivatives.

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Section: Introductionmentioning

confidence: 99%

Spectral Derivatives of Optical Depth for Partitioning Aerosol Type and Loading

et al. 2021

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“…Although the corresponding Ångström exponent can also be applied for describing this wavelength dependence (e.g., Delene & Ogren, 2002), such an alternative is not considered in our initial analysis. It should be noted that the SCA_ratio represents a quite narrow spectral range (0.45–0.7 μm); thus, it is mostly sensitive to the submicron particles (e.g., Atkinson et al, 2018). In other words, the SCA_ratio alone is not well suited for describing a link between the light scattering and PM 10,v .…”

Section: Approachmentioning

confidence: 99%

Aerosol Total Volume Estimation From Wavelength‐ and Size‐Resolved Scattering Coefficient Data: A New Method

Kassianov

Pekour

Berg

et al. 2020

Earth and Space Science

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While the importance of supermicron particles on human health and climate is well recognized, knowledge of their size-related properties remains elusive. Many routine near-surface in situ measurements of aerosol properties include size spectra of submicron particles and aerosol total scattering coefficient at three visible wavelengths and two size cutoffs. These properties are collected, for example, at the U.S. Department of Energy's Atmospheric Radiation Measurement (ARM) user facility. Our study illustrates how these conventional measurements can be used to predict total particle volume (particle size <10 μm). The well-known fact that small and large particles scatter sunlight very differently forms the basis of a new method. Our study demonstrates a good agreement between estimated and measured total volumes for five climate-important locations. The agreement suggests that the new method can be used to predict the total particle volume from the routine data collected at numerous sites around the world. Plain Language Summary Particles in the air are astonishingly diverse in terms of size. Determining their size distribution, which characterizes the number of particles for every size of interest, is a difficult technical problem due to an extremely wide range of sizes (several orders of magnitude) and lack of a single instrument that can measure over the entire size range. For example, most conventional particle sizing techniques cannot measure large particles (size >1 μm) despite their recognized importance for human health, environment, and climate. Here, a new method is introduced to indirectly estimate the volume of large particles, which is closely related to their size distribution. This method combines (1) routinely measured size distributions of small particles and (2) the well-known fact that small and large particles scatter sunlight very differently as a function of wavelength. The performance of this method is demonstrated for data collected at five sites characterized by continental, alpine, coastal, and marine environments. The good agreement between the estimated and the measured values of the total volume of small and large particles demonstrates the credibility of this method and highlights its potential application to routine aerosol measurements made at numerous locations around the world.

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“…In the most controlled experiments, volume-sampled SMF estimates are compared with FMF retrievals derived from applying the SDA to volume-sampled, three-channel CRD (cavity ring-down) or three-channel nephelometer "spectra" (Atkinson et al, 2010;Kaku et al, 2014 (Ka); Atkinson et al, 2018). In general we find, as expected, the SMF to be FMF in Atkinson et al (2010) and Ka: this is notably true at the near-IR (700 nm) wavelength in Ka (ACE-Asia data of their Fig.…”

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Relationship between the sub-micron fraction (SMF) and fine-mode fraction (FMF) in the context of AERONET retrievals

et al. 2023

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Abstract. The sub-micron (SM) aerosol optical depth (AOD) is an optical separation based on the fraction of particles below a specified cutoff radius of the particle size distribution (PSD) at a given particle radius. It is fundamentally different from spectrally separated FM (fine-mode) AOD. We present a simple (AOD-normalized) SM fraction versus FM fraction (SMF vs. FMF) linear equation that explains the well-recognized empirical result of SMF generally being greater than the FMF. The AERONET inversion (AERinv) products (combined inputs of spectral AOD and sky radiance) and the spectral deconvolution algorithm (SDA) products (input of AOD spectra) enable, respectively, an empirical SMF vs. FMF comparison at similar (columnar) remote sensing scales across a variety of aerosol types. SMF (AERinv-derived) vs. FMF (SDA-derived) behavior is primarily dependent on the relative truncated portion (εc) of the coarse-mode (CM) AOD associated with the cutoff portion of the CM PSD and, to a second order, the cutoff FM PSD and FM AOD (εf). The SMF vs. FMF equation largely explains the SMF vs. FMF behavior of the AERinv vs. SDA products as a function of PSD cutoff radius (“inflection point”) across an ensemble of AERONET sites and aerosol types (urban-industrial, biomass burning, dust, maritime and a mixed class of Arctic aerosols). The overarching dynamic was that the linear SMF vs. FMF relation pivots clockwise about the approximate (SMF, FMF) singularity of (1, 1) in a “linearly inverse” fashion (slope and intercept of approximately 1−εc and εc) with increasing cutoff radius. SMF vs. FMF slopes and intercepts derived from AERinv and SDA retrievals confirmed the general domination of εc over εf in controlling that dynamic. A more general conclusion is the apparent confirmation that the optical impact of truncating modal (whole) PSD features can be detected by an SMF vs. FMF analysis.

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Using spectral methods to obtain particle size information from optical data: applications to measurements from CARES 2010

Cited by 4 publications

References 43 publications

Spectral Derivatives of Optical Depth for Partitioning Aerosol Type and Loading

Spectral Derivatives of Optical Depth for Partitioning Aerosol Type and Loading

Aerosol Total Volume Estimation From Wavelength‐ and Size‐Resolved Scattering Coefficient Data: A New Method

Relationship between the sub-micron fraction (SMF) and fine-mode fraction (FMF) in the context of AERONET retrievals

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