Title :
Evaluation of spherical particle sizes with an asymmetric illumination microscope
Author :
Ramella-Roman, Jessica C. ; Bargo, Paulo R. ; Prahl, Scott A. ; Jacques, Steven L.
Author_Institution :
Oregon Health & Sci. Univ., Portland, OR, USA
Abstract :
A polarized microscope system is used to perform goniometric measurements of light scattered by small particles. The light incident angle on a sample of monodispersed latex microspheres is increased sequentially and a microscope objective lens collects scattered light from the samples. Light is only collected at angles greater than the objective lens numerical aperture (NA) so that only light scattered by the spheres is collected. The experimental results were modeled with a Mie theory-based algorithm. Experiments conducted with microspheres of diameter 1.03, 2.03, and 6.4 μm show that, by decreasing the objective lens NA from NA=0.55 to NA=0.0548, a more distinguishable scattering pattern is detectable. From these highly shaped curves, we found that the size of a sphere of nominal diameter 2.03 μm was 2.11 ±0.06 μm and a 6.4 μm sphere was 6.34 ±0.07 μm.
Keywords :
bio-optics; biological techniques; cellular biophysics; disperse systems; light scattering; optical microscopes; particle size measurement; 1.03 micron; 2.03 micron; 6.4 micron; Mie theory-based algorithm; asymmetric illumination microscope; cell nuclei; diameter; early cancer diagnosis; goniometric measurements; highly shaped curves; light incident angle; microscope objective lens; microspheres; monodispersed latex microspheres; nominal diameter; objective lens numerical aperture; polarized microscope system; scattered light; scattering pattern; small particles; spherical particle sizes; Apertures; Lenses; Light scattering; Lighting; Microscopy; Mie scattering; Optical polarization; Particle measurements; Particle scattering; Performance evaluation;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2003.811289
