Optical microscopy simple microscopes

In this era of automatic titrators, microprocessor-controlled thermal analysis, and definitive spectral techniques, one of the most powerful techniques, that is, optical microscopy, is frequently overlooked. The value of direct sample observation, preferably while it is exposed to different relative humidities, cannot be overstated. In the author s laboratory, a plexiglass chamber was constructed that can be placed on the stage of the microscope, through which air of known humidity can be circulated. This simple technique has been very useful in examining the swelling (or lack) of disintegrants and the influence of very hydrophilic excipients in combination with a moisture sensitive drug. ... 

The reflection technique is more limited in resolution and magnification than is transmission. Reflection optical microscopy of adhered surfaces is often revealing, but the very limited depth of field is a severe handicap. Nevertheless, examination of surfaces after testing or failure is a simple, but important, first step in determining locus of failure (see Stress distribution mode of failure). Surface reflectivity of specimens is often improved by deposition of a layer or metal. The reflection microscope is especially useful when operated in dark-field mode, where topographical differences are accentuated. 

The simplest method is optical microscopy, in which visible light (photons) is used to observe a sample. It has a resolution limit around 0.25-0.5 pm, which is on the order of 2/2, where 2 is the wavelength of incident light. From a strict colloid science point of view, it lies near the upper limit of colloid particle sizes and appears to be of limited utility. However, it is of great help in the identification of minerals, because it allows observation of crystal habits (the shape and size of crystals, which are determined by their internal symmetry). With experience, many minerals can be identified in a soil sample under a microscope, even from simple inspection. A unique feature of optical microscopy is the availability of polarized light, which is handy in distinguishing minerals or even different crystal types of the same compound (Bullock et al. 1985 Cady, Wilding, and Drees 2010). 

One of the most powerful and simple techniques in the characterization of liquid crystal phases is polarized optical microscopy (POM). Using this technique, we can take advantage of the birefringence of liquid crystals to identify different phases. The sample is placed between crossed polarizers on the optical microscope and viewed in transmission. The illuminating light passes through a linear polarizer, the sample, and then a second linear polarizer crossed with the first. 

Dual-wavelength TCSPC detection in two-photon laser scanning microscopes is relatively simple [37]. Multispectral TCSPC detection in a two-photon laser scanning microscope requires a suitable relay optics between the objective lens and the polychromator [35, 60]. Details are described under TCSPC Laser Scanning Microscopy . 

When applicable, dark field microscopy offers a relatively simple method for particulate diagnostics. The method has a useful size range of 0.05-0.8 pm. The equipment required is a standard optical microscope, equipped with q ropriate optics, in particular, the numerical aperture of the objective loos and a cardioid condenser. 

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