Prediction of Aerosol Particle Size Distribution Based on Neural Network

Ren, Yali; Mao, Jiandong; Zhao, Huijing; Zhou, Chunyan; Gong, Xinglong; Rao, Zhimin; Wang, Qiang; Zhang, Yi

doi:10.1155/2020/5074192

Cited by 8 publications

(2 citation statements)

References 10 publications

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“…Several past studies have applied machine learning to aerosol scattering and optics. Chen et al (2022) used a neural network to represent scattering by spheroidal dust particles, Yu et al (2022) trained a large neural network on a database of non-spherical particles to predict particle optics, and Ren et al (2020) trained a neural network to predict information about aerosol size distributions from photometer observations of AOPs. Both Thong and Yoon (2022) and Stremme (2019) trained neural networks to directly emulate a Mie scattering model.…”

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confidence: 99%

NeuralMie (v1.0): An Aerosol Optics Emulator

Geiss,

2024

Preprint

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Abstract. The direct interactions of atmospheric aerosols with radiation significantly impact the Earth's climate and weather and are important to represent accurately in simulations of the atmosphere. This work introduces two new contributions to enable more accurate representation of aerosol optics in atmosphere models: 1) "TAMie," a new Python-based Mie scattering code that can represent both homogeneous and coated particles and achieves comparable speed and accuracy to established Fortran Mie codes. 2) "NeuralMie," a neural network Mie code emulator trained on data from TAMie, that can directly compute the bulk optical properties of a diverse range of aerosol populations and is appropriate for use in atmosphere simulations where aerosol optical properties are parameterized. NeuralMie is highly flexible and can be used for a large range of particle types and wavelengths. It can represent core-shell scattering, and by directly estimating bulk optical properties, is more efficient than existing Mie code and Mie code emulators while incurring negligible error (0.08 % mean absolute percentage error).

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confidence: 99%

NeuralMie (v1.0): An Aerosol Optics Emulator

Geiss,

2024

Preprint

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“…Although the particle size distribution of aerosol particle is likely a log-normal distribution (Yali et al, 2020), the mean radius in the equation above is chosen based on a simple uniform-in-size aerosol particle size distribution due to our instrument limitation in determining the standard deviation that is important in specifying the exact log-normal size distribution for our particle cloud. For example in a log-normal distribution changing the standard deviation from 0.5 to 0.75 and 1, the resulting means are practically the same as that of the normal distribution in the size range of 0.5-1 micron, 1-2.5 micron, and 2.5-5 micron.…”

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confidence: 99%

Effectiveness of the new ambulance air exhaust system in reducing aerosol particle concentration

Petrangsan

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The objective of this work is to assess the effectiveness in reducing airborne particles of the Camfil? CC410-concealed air exhaust system, that is installed in the ER-1 ambulance (a King Chulalongkorn Memorial Hospital ambulance). This is done by diffusing aerosols into the cabin at the patient's face position for an injection period (IP) of 1 minute and measuring the aerosol concentration inside the cabin over time. The experiment is conducted for 2 ventilation conditions, when the exhaust system is off (Minimal Ventilation: MV) and at maximum speed (High Ventilation: HV). Density of the aerosol is interpreted in terms of its volume concentration. Time period is counted at the end of the IP. Aerosol is found to disperse toward the cabin's frontal part and then throughout the entire cabin shortly after IP. Its spatial distribution is non-uniform with multiple local peaks, differs between the two cases. Particles of different size range is removed from the cabin with different rates. Without an aid from the exhaust system (MV case), larger particles tend to decay relatively faster. To recover aerosol concentration to that comparable' to the initial (or background) state for the MV case, it takes 16�minutes for 0.5-1 microns, 12 minutes for 1-2.5 microns, and 9 minutes for 2.5-5 microns particles. The background state is reached after 18 minutes for all size ranges. With the aid in the HV case, the decaying period is shortened to about 5 minutes for all aerosol size ranges. During the passive decay (MV), small aerosols tend to aggregate in the rear cabin and larger aerosols in the front (close to the diffusion nozzle), reflecting their native dispersion ability (or inability) with respect to their sizes. Aerosol of medium-to-large 1-5 microns range is relatively large at the cabin frontal part (seat 1) but 0.5-1 microns range is large at the cabin rear (seat 5). During the active decay (HV), on the other hand, larger particle is advected toward the middle and rear parts. Small-to-medium-size aerosols at 0.5-2.5 microns is concentrated at the cabin frontal part (seat 2) while that of 2.5-5 microns concentration is peaked in the middle (seat 3) and on average in the rear (seat 5). The air exhaust system is proven satisfactory effective in reducing aerosol concentration in the ambulance cabin. Considering among seats and particle size in this experiment, the system is able to reduce peak aerosol concentrations by 25% and temporal-averaged concentration by 70%.

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Potential of Raman‐Reflectance Combination in Quantifying Liver Steatosis and Fat Droplet Size: Evidence From Monte Carlo Simulations and Phantom Studies

Guo,

Zions,

Law

et al. 2024

Journal of Biophotonics

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This study explores a combined strategy of Raman and reflectance spectroscopy for quantifying liver fat content and fat droplet size, crucial in assessing donor livers. By using Monte Carlo simulations and experimental setups with oil‐in‐water phantoms, our findings indicate that Raman scattering can solely differentiate between varying fat contents. At the same time, reflectance intensity is influenced by both fat content and oil droplet size, with a more pronounced sensitivity to fat droplet size. This study demonstrates the efficacy of combined Raman and reflectance spectroscopy in assessing liver steatosis and fat droplet size, potentially aiding in assessing donor livers for transplantation.

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Prediction of Aerosol Particle Size Distribution Based on Neural Network

Cited by 8 publications

References 10 publications

NeuralMie (v1.0): An Aerosol Optics Emulator

NeuralMie (v1.0): An Aerosol Optics Emulator

Effectiveness of the new ambulance air exhaust system in reducing aerosol particle concentration

Potential of Raman‐Reflectance Combination in Quantifying Liver Steatosis and Fat Droplet Size: Evidence From Monte Carlo Simulations and Phantom Studies

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