Size dependence of optical properties and internal structure of plasma grown carbonaceous nanoparticles studied by <i>in situ</i> Rayleigh-Mie scattering ellipsometry

Hong, Suk–Ho; Winter, J.

doi:10.1063/1.2338132

Cited by 59 publications

(52 citation statements)

References 58 publications

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“…However, when the size of the particles exceeds this threshold of λ/10 then Rayleigh scattering is replaced by anisotropic Mie scattering where the scattered light is unequal in energy (inelastic scattering) to the incident light and angle-dependent ( Fig. 1) [30] where the scattered light is most intense towards the direction of the incident light [31]. This size threshold (λ/10) is due to the way electromagnetic waves (e.g., light) interact with a particle and falls beyond the scope of this review although excellent textbooks and reference literature are available for consultation [32,33].…”

Section: Scattering Of Light By Particlesmentioning

confidence: 99%

DLS and zeta potential – What they are and what they are not?

Bhattacharjee

2016

Journal of Controlled Release

2,802

1,673

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Section: Scattering Of Light By Particlesmentioning

confidence: 99%

DLS and zeta potential – What they are and what they are not?

Bhattacharjee

2016

Journal of Controlled Release

2,802

1,673

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“…A comparable technique termed "Mie scattering ellipsometry" (MSE) is used in plasma physics [101,102]. Main focus in MSE applications has been the determination of particle size and size distribution for particles created in plasmas [103][104][105], e.g. for process control in dust sensitive micro device fabrication.…”

Section: Ellipsometric Light Scatteringmentioning

confidence: 99%

Light scattering near and from interfaces using evanescent wave and ellipsometric light scattering

Sigel

2009

Current Opinion in Colloid & Interface Science

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The broad range of interface light scattering investigations in recent years shows the power and the versatility of these techniques to address new and open questions in colloid and interface science and the soft condensed matter field. Structural information for polymers, liquid crystals, or colloids close to planar or spherical colloidal interfaces are either captured with long range light scattering resolution, or in a complementary approach by high resolution ellipsometric techniques. Of special interest is the dynamic behavior close to or in interfaces, since it determines material properties and responses to external fields. Due to the broad dynamical range and the high scattering contrast for visible light, interface light scattering is a key to elucidate soft matter interfacial dynamics. This contribution reviews experimental and related theoretical approaches for interface light scattering and further gives an overview of achievements based on such techniques.

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“…Another argument for an effectively constant value of S p can be based on measurements (Hong and Winter 2006) that show the refractive index function, f (m), decreases with increasing primary particle size. Real-time nanoparticle growth and scattering measurements for hydrocarbon particles in plasma demonstrate that the imaginary component of the complex refractive index decreases with increasing particle size.…”

Section: Size Uniformity Of Primary Particlesmentioning

confidence: 99%

“…The estimate for overall accuracy uncertainty of S p is based on compensating levels of uncertainty for d p (±12-15%) and f (m)/ρ p (±12-15%), as described by Hong and Winter, 2006. …”

Section: Total Accuracy and Precision Estimatesmentioning

confidence: 99%

Two-Angle Ratio Scattering (STAR) Method for Real-Time Measurement of Agglomerate Soot Concentration and Size: Theory

Holve¹

2011

Aerosol Science and Technology

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The Scattering by Two-Angle Ratio (STAR) light scattering method described in this article is based on a new analysis of a well-established theory in the literature that describes black carbon soot as fractal agglomerates. Previous analyses have shown that the measured scattering signals at two appropriate angles can be used to determine the mean agglomerate particle size and mass concentration. The current work shows that a dimensionless invariant function of the two-angle scattering ratio can be defined (C m #), for computation of the mass concentration and mean agglomerate size. In addition, the three soot optical properties can be combined into one overall soot property constant, S p , which, based on literature measurements of each component property, is also near invariant for a variety of fuel and combustor conditions. Research literature on optical parameters has been used (without resorting to arbitrary calibrations) to compute values of the gas phase soot mass concentration. In a companion article (Holve et al. 2011), measurements of diesel and gas turbine engines show that the model for interpreting scattering measurements from STAR is in reasonable agreement with gravimetric measurements.

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Size dependence of optical properties and internal structure of plasma grown carbonaceous nanoparticles studied by in situ Rayleigh-Mie scattering ellipsometry

Cited by 59 publications

References 58 publications

DLS and zeta potential – What they are and what they are not?

DLS and zeta potential – What they are and what they are not?

Light scattering near and from interfaces using evanescent wave and ellipsometric light scattering

Two-Angle Ratio Scattering (STAR) Method for Real-Time Measurement of Agglomerate Soot Concentration and Size: Theory

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