dark field microscopy,dark field microscope,darkfield microscope,darkfield microscopy
We are dark field microscopy,dark field microscope manufacturer.Welcome OEM.

field and dark field microscopy ppt

What is dark field microscopy?

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

All of us are quite familiar with the appearance and visibility of stars on a dark night, this despite their enormous distances from the Earth. Stars can be readily observed at night primarily because of the stark contrast between their faint light and the black sky.

Yet stars are shining both night and day, but they are invisible during the day because the overwhelming brightness of the sun “blots out” the faint light from the stars, rendering them invisible. During a total solar eclipse, the moon moves between the Earth and the sun blocking out the light of the sun and the stars can now be seen even though it is daytime. In short, the visibility of the faint star light is enormously enhanced against a dark background.

bright field and dark field microscopy ppt,brightfield and darkfield microscopy ppt

This principle is applied in darkfield (also called darkground) microscopy, a simple and popular method for making unstained transparent specimens clearly visible. Such objects often have refractive indices very close in value to that of their surroundings and are difficult to image in conventional brightfield microscopy. For instance, many small aquatic organisms have a refractive index ranging from 1.2 to 1.4, resulting in a negligible optical difference from the surrounding aqueous medium. These are ideal candidates for dark field microscopy.

dark field microscopy requires blocking out of the central light which ordinarily passes through and around (surrounding) the specimen, allowing only oblique rays from every azimuth to “strike” the specimen mounted on the microscope slide. The top lens of a simple Abbe darkfield condenser is spherically concave, allowing light rays emerging from the surface in all azimuths to form an inverted hollow cone of light with an apex centered in the specimen plane. If no specimen is present and the numerical aperture of the condenser is greater than that of the objective, the oblique rays cross and all such rays will miss entering the objective because of their obliquity. The field of view will appear dark.

The darkfield condenser/objective pair illustrated in Figure 1 is a high-numerical aperture arrangement that represents darkfield microscopy in its most sophisticated configuration, which will be discussed in detail below. The objective contains an internal iris diaphragm that serves to reduce the numerical aperture of the objective to a value below that of the inverted hollow light cone emitted by the condenser. The cardioid condenser is a reflecting darkfield design that relies on internal mirrors to project an aberration-free cone of light onto the specimen plane.

When a specimen is placed on the slide, especially an unstained, non-light absorbing specimen, the oblique rays cross the specimen and are diffracted, reflected, and/or refracted by optical discontinuities (such as the cell membrane, nucleus, and internal organelles) allowing these faint rays to enter the objective. The specimen can then be seen bright on an otherwise black background. In terms of Fourier optics, dark field microscopy removes the zeroth order (unscattered light) from the diffraction pattern formed at the rear focal plane of the objective. This results in an image formed exclusively from higher order diffraction intensities scattered by the specimen.

The photomicrographs in Figure 2 illustrate the effects of darkfield and brightfield illumination on silica skeletons from a small marine protozoan (radiolarian) in a whole mount specimen. In ordinary brightfield, skeletal features of the radiolarian are not well defined and tend to be washed out in photomicrographs recorded either with traditional film or digitally captured. was taken in brightfield illumination with the condenser aperture diaphragm closed to a point where diffraction artifacts obscure some of the sample detail. This enhances specimen contrast at the expense of image distortion. Under dark field microscopy, more detail is present, especially in the upper portion of the organism, and the image acquires an apparent three-dimensional appearance. When a red filter is used in conjunction with a darkfield stop , the radiolarian takes on a colorful appearance that is more pleasing, although no additional detail is produced and there is even some reduction in image quality.

Specimens that have smooth reflective surfaces produce images due, in part, to reflection of light into the objective. In situations where the refractive index is different from the surrounding medium or where refractive index gradients occur (as in the edge of a membrane), light is refracted by the specimen. Both instances of reflection and refraction produce relatively small angular changes in the direction of light, allowing some to enter the objective. In contrast, some light striking the specimen is also diffracted, producing a 180-degree arc of light that passes through the entire numerical aperture range of the objective. The resolving power of the

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

What is Bright field microscopy?

Bright-field microscopy is the simplest of all the optical microscopy illumination techniques. Sample illumination is transmitted (i.e., illuminated from below and observed from above) white light, and contrast in the sample is caused by attenuation of the transmitted light in dense areas of the sample. Bright-field microscopy is the simplest of a range of techniques used for illumination of samples in light microscopes, and its simplicity makes it a popular technique. The typical appearance of a bright-field microscopy image is a dark sample on a bright background, hence the name.

Bright field microscopy Light path

The light path of a bright-field microscope is extremely simple, no additional components are required beyond the normal light-microscope setup. The light path therefore consists of:

a transillumination light source, commonly a halogen lamp in the microscope stand;
a condenser lens, which focuses light from the light source onto the sample;
an objective lens, which collects light from the sample and magnifies the image;
oculars and/or a camera to view the sample image.

Bright-field microscopy may use critical or Köhler illumination to illuminate the sample.

Bright field microscopy Performance

Bright-field microscopy typically has low contrast with most biological samples, as few absorb light to a great extent. Staining is often required to increase contrast, which prevents use on live cells in many situations. Bright-field illumination is useful for samples that have an intrinsic color, for example chloroplasts in plant cells.Bright-field microscopy is a standard light-microscopy technique, and therefore magnification is limited by the resolving power possible with the wavelength of visible light.

Bright field microscopy Advantages

Simplicity of setup with only basic equipment required.
Living cells can be seen with bright-field microscopes

Bright field microscopy Limitations

Very low contrast of most biological samples.
The practical limit to magnification with a light microscope is around 1300X. Although higher magnifications are possible, it becomes increasingly difficult to maintain image clarity as the magnification increases.
Low apparent optical resolution due to the blur of out-of-focus material.
Samples that are naturally colorless and transparent cannot be seen well, e.g. many types of mammalian cells. These samples often have to be stained before viewing. Samples that do have their own color can be seen without preparation, e.g. the observation of cytoplasmic streaming in Chara cells.

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

field and dark field microscopy ppt

Bright field microscopy Enhancements

Reducing or increasing the amount of the light source by the iris diaphragm.
Use of an oil-immersion objective lens and a special immersion oil placed on a glass cover over the specimen. Immersion oil has the same refraction as glass and improves the resolution of the observed specimen.
Use of sample-staining methods for use in microbiology, such as simple stains (methylene blue, safranin, crystal violet) and differential stains (negative stains, flagellar stains, endospore stains).
Use of a colored (usually blue) or polarizing filter on the light source to highlight features not visible under white light. The use of filters is especially useful with mineral samples.

 

bright field and dark field microscopy ppt

Lect08_Bi177_ContrastResolution dark field microscopy ppt dark field microscopy ppt Dark Field Illumination pdf ppt

Have any question, Please enter the form below and click the submit button.


*
*
*
*
1 + 8 = ?
Please enter the answer to the sum & Click Submit to verify your registration.

Related Items