Dual-wavelength light scattering for selective detection of volcanic ash particles

Jurányi, Z.; Burtscher, H.; Loepfe, M.; Nenkov, M.; Weingärtner, E.

doi:10.5194/amtd-8-8701-2015

Cited by 2 publications

(1 citation statement)

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“…Under the high-temperature coal combustion condition, the coal-generated micron and submicron particles are mostly spherical given the mechanism of vaporization/condensation of the mineral elements in coal [24,26]. For many other particle measurement fields, particles, such as ash particles in fluidized bed furnace, sea-salt particles, soot aggregates, volcanic particles, and other dust particles in the atmosphere, exhibit an irregular shape [46,47,48,49], so the adaptability of this method to irregular particles should be taken into consideration. Recently, some research studies have assessed the scattering character of nonspherical particles with discrete dipole approximation (DDA) [50] and T-Matrix methods [51].…”

Section: Resultsmentioning

confidence: 99%

A New Angular Light Scattering Measurement of Particulate Matter Mass Concentration for Homogeneous Spherical Particles

Chen

Liu

Han

et al. 2019

Sensors

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Under the condition of ultra-low emission for power plants, the particulate matter concentration is significantly lower than that of typical power plants a decade ago, which posed new challenges for the particulate matter monitoring of stationary emission. The monitoring of particulate matter mass concentration based on ensemble light scattering has been found affected by particle size. Thus, this study develops a method of using the scattering angular distribution to obtain the real-time particle size, and then correct the particulate matter concentration with the real-time measured particle size. In this study, a real-time aerosol concentration and particle size measurement setup is constructed with a fixed detector at the forward direction and a rotating detector. The mass concentration is measured by the fixed detector, and the particle size is measured from the intensity ratio of the two detectors. The simulations show that the particle size has power law functionality with the angular spacing of the ripple structure according to Mie theory. Four quartz aerosols with different particle size are tested during the experiment, and the particle size measured from the ripple width is compared with the mass median size measured by an electrical low pressure impactor (ELPI). Both techniques have the same measurement tendency, and the measurement deviation by the ripple width method compared with ELPI is less than 15%. Finally, the measurement error of the real-time mass concentration is reduced from 38% to 18% with correction of the simultaneously measured particle size when particle size has changed.

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