Particle laser light diffraction

The surface mean diameter is the diameter of a sphere of the same surface area-to-volume ratio as the actual particle, which is usually not a perfect sphere. The surface mean diameter, which is sometimes referred to as the Sauter mean diameter, is the most useful particle size correlation, because hydrodynamic forces in the fluid bed act on the outside surface of the particle. The surface mean diameter is directly obtained from automated laser light diffraction devices, which are commonly used to measure particle sizes from 0.5 to 600 p.m. X-ray diffraction is commonly used to measure smaller particles (see Size TffiASURETffiNT OF PARTICLES). 

The particle size analyzer, based on laser light diffraction, consists of a laser source, beam expander, collector lens, and detector (Fig. ] 3.45). The detector contains light diodes arranged to form a radial diode-array detector. The particle sample to be measured can be blown across the laser beam (dry sample), or it can be circulated via a measurement cell in a liquid suspension. In the latter case, the beam is direaed through the transparent cell. 

The vesicle size is an important parameter not only for in-process control but particularly in quality assurance, because the physical stability of the vesicle dispersion depends on particle size and particle size distribution. An appropriate and particularly quick method is laser light scattering or diffraction. Laser light diffraction can be applied to particles > 1 pm and refers to the proportionality between the intensity of diffraction and the square of the particle diameter according to the diffraction theory of Fraunhofer. 

Frake et al. compared various chemometric approaches to the determination of the median particle size in lactose monohydrate with calibration models constrncted by MLR, PLS, PCR or ANNs. Overall, the ensuing models allowed mean particle sizes over the range 20-110/tm to be determined with an error less than 5 pm, which is comparable to that of the laser light diffraction method nsed as reference. Predictive ability was similar for models based on absorbance and second-derivative spectra this confirms that spectral treatments do not suppress the scattering component arising from differences in particle size. 

The characterization of emulsions by particle size distribution analysis has been facilitated in recent years by a range of new instruments. Most of these instruments employ laser light diffraction principles, and have replaced older spectrophotometric methods. 

Particle size is an important property with respect to the sensory quality of chocolate, and in chocolate manufacture. It can be measured using laser light diffraction spectrophotometry (see Section 22.2.11.2), and by a variety of other means such as micrometry, microscopy, wet sieve fractionation, sedimentation and Coulter counting (Minifie, 1999). 

Table 2 compares the estimated Mayer Stowe median particle size D with the corresponding median particle size diameter D50 measured by laser light diffraction... 

Kanerva H, Kiesvaara J, Muttonen E, Yliruusi J. Use of laser light diffraction in determining the size distribution of different shaped particles. Pharm Ind 1993 55 849 - 853. 

Coulter LS Series particle size distribution analyser Laser light diffraction 0.1-810 pm 60 Particle sizing... 

Figure 8.16 Typical result of a particle size distribution obtained by laser light diffraction.

Figure 8.17 Comparison of particle size distribution measurements by laser light diffraction and sieve analysis. In part (a), it can be seen that the overall agreement is ve7 good. Part (b) shows the result of sieving of a ve7...

For spherical particles, the measured particle size distribution by laser light diffraction and sieving may be very similar (Figure 8.17). 

For rodhke particles, sieving essentially determines the diameter of the rod, whereas laser light diffraction determines the diameter of a sphere with same volume as the rod. Therefore, the result obtained by sieving will be smaller than that obtained by laser light diffraction. The opposite applies for platelike particles, where sieving measures the diameter of the plate. 

Figure 5.11 Particle size distribution measured with static laser light diffraction of PMMA particles filled with SiOi nanoparticles and TEM picture of the core-shell nanoparticles.

Brown, D. I, Felton, P. G., Direct Measurement of Concentration and Size for Particles of Different Shapes using Laser Light Diffraction, Ghent Eng. Res. Des., 1985, 63, 125-132. 

Kouzelis, D., Candel, S. M., Esposito, E., Zikikout, S., Particle Sizing by Laser Light Diffraction Improvements in Optics and Algorithms,Part Charact, 1987,4, 151-156. Bayvel, L. P., Knight, J., Roberston, G., Alternative Model-Independent Inversion Programme for Malvern Particle Sizer, Part Charact, 1987,4,49-53. 

Particle Size. Wet sieve analyses are commonly used in the 20 )J.m (using microsieves) to 150 )J.m size range. Sizes in the 1—10 )J.m range are analyzed by light-transmission Hquid-phase sedimentation, laser beam diffraction, or potentiometric variation methods. Electron microscopy is the only rehable procedure for characterizing submicrometer particles. Scanning electron microscopy is useful for characterizing particle shape, and the relation of particle shape to slurry stabiUty. 

The laser diffraction meter consists of a parallel monochromatic light beam, 7 mm in diameter, from a 5-mW helium-neon laser, transmitted across the spray. Light diffracted by droplets and particles produces a Fraunhofer diffraction pattern. Light from the diffraction pattern is collected by 31 semicircular photosensitive rings, and the hght energies... 

Merkku, P. Yliruusi, J. Kristoffersson, E. Particle size determination of some pharmaceutical fillers by laser light 47. diffraction part II. Acta Pharm. Nord. 1992, 4 (4),... 

The first question we will examine in this paper is do these micrometer particles really exist Laser diffraction spectroscopy analyses the angular intensity spectrum of diffracted laser light and... 

The newer la.ser diffraction instrument allows measurement for particle sizes ranging from 0.1 pm to 8 mm (7). Most of the laser diffraction instruments in the pharmaceutical industry use the optical model based on several theories, either Fraunhofer, (near-) forward light scattering, low-angle laser light scattering, Mie, Fraunhofer approximation, or anomalous diffraction. These laser diffraction instruments assume that the particles measured are spherical. Hence, the instrument will convert the scattering pattern into an equivalent volume diameter. A typical laser diffraction instrument consists of a laser, a sample presentation system, and a series of detectors. 

FIG. 21-9 (a) Diffraction patterns of laser light in forward direction for two different particle sizes, (b) The angular distribution 7(9) is converted by a Fourier lens to a spatial distribution l(r) at the location of the photodetector, (c) Intensity distribution of a small particle detected by a semicircular photodetector. 

FIG. 21-10 Calculated diffraction patterns of laser light in forward direction for nonspherical particles square, pentagon, and floccose. All diffraction patterns show a symmetry to 180°. 

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