Rockburst in underground excavations: A review of mechanism, classification, and prediction methods

Dynamic light scattering (DLS) measures time-dependent fluctuations in the scattering intensity arising from particles undergoing random Brownian motion. Diffusion coefficient and particle size information can be obtained from the analysis of these fluctuations. This paper discusses the factors which will influence the lower size limit of DLS and reports the use of sucrose as a test sample to probe this lower limit of the technique. Hydrodynamic diameter values of less than 1 nm are obtained by the use of 173°backscatter detection that is applied to increase the sensitivity of DLS. The peak means (with standard deviations) obtained for the intensity and volume data from a series of sucrose concentrations, ranging from 5 to 35% w/v, were measured as D I,Mean = 0.82 nm (0.11 nm) and D V,Mean = 0.62 nm (0.05 nm), respectively. These sucrose results suggest that sub nanometer measurements are achievable with a precision of 0.1 nm. Evidence to support these size results for sucrose is discussed.

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Dynamic light scattering as a relative tool for assessing the molecular integrity and stability of monoclonal antibodies

Nobbmann

Connah

Fish

et al. 2007

Biotechnology and Genetic Engineering Reviews

177

106

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Resolving Concentrated Particle Size Mixtures Using Dynamic Light Scattering

Kaszuba¹,

Connah²,

McNeil-Watson³

et al. 2007

Part & Part Syst Charact

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Dynamic light scattering (DLS) is a technique used for measuring the size of molecules and particles undergoing Brownian motion by observing time‐dependent fluctuations in the intensity of scattered light. The measurement of samples using conventional DLS instrumentation is limited to low concentrations due to the onset of a phenomenon called multiple scattering. The problems of multiple scattering have been addressed in a light scattering instrument incorporating non‐ invasive backscatter optics (NIBS). This novel optic arrangement maximizes the detection of scattered light while maintaining signal quality and allows for measurements of turbid samples. This paper discusses the ability of backscatter detection to accurately determine particle sizes at 1 %w/v sample concentrations and demonstrates the correct resolution of different size populations using a series of latex standard mixtures with known volume ratios. The concentration of 1 %w/v is much higher than can be measured on conventional dynamic light scattering instruments.

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High Resolution Zeta Potential Measurements: Analysis of Multi-component Mixtures

Connah¹,

Kaszuba²,

Morfesis³

2002

Journal of Dispersion Science and Technology

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Protein and Nanoparticle Characterisation Using Light Scattering Techniques

Kaszuba¹,

Connah²

2006

Part & Part Syst Charact

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The technique of dynamic light scattering is well suited to the measurement of the size of colloidal dispersions. Traditionally, measurements of large particle sizes or particles that are highly scattering would require high dilution of the sample in order to avoid multiple scattering effects. Conversely, measurement of very small and/or poorly scattering particles or samples that are very dilute are difficult unless high‐powered lasers are used. These problems have been addressed in a light scattering instrument incorporating novel non‐invasive backscatter optics (NIBS). This novel optic arrangement maximises the detection of scattered light while maintaining signal quality. In addition to the increased size and concentration range for DLS applications, the increased sensitivity obtained from this optical arrangement also allows for the determination of absolute molecular weight using static light scattering measurements. Accurate molecular weight measurements can be achieved at a single scattering angle for molecules that do not show any angular dependence in their scattering intensity. This paper describes the advantages of using backscatter optics and illustrates the capabilities of the technology by reporting results of measurements from various applications.

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Malcolm T. Connah

Measuring sub nanometre sizes using dynamic light scattering

Dynamic light scattering as a relative tool for assessing the molecular integrity and stability of monoclonal antibodies

Resolving Concentrated Particle Size Mixtures Using Dynamic Light Scattering

High Resolution Zeta Potential Measurements: Analysis of Multi-component Mixtures

Protein and Nanoparticle Characterisation Using Light Scattering Techniques

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