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The optical microscope, often referred to as the "light microscope", is a type of microscope which uses visible light and a system of lenses to magnify images of small samples. Optical microscopes are the oldest and simplest of the microscopes.
There are non-optical microscopes, which require chemical or ion staining of non-living samples, and can magnify exponentially greater than the optical microscope. See: scanning electron microscope, transmission electron microscope.
Additional recommended knowledge
There are two basic configurations of optical microscope in use, the simple (one lens) and compound (many lenses).
Simple optical microscope
A simple microscope is a microscope that uses only one lens for magnification, and is the original light microscope. Van Leeuwenhoek's microscopes consisted of a small, single convex lens mounted on a plate, with a mechanism to hold the sample or specimen to be examined. Demonstrations by British microscopist Brian J. Ford have produced surprisingly detailed images from such basic instruments. Though now considered primitive, the use of a single, convex lens for viewing is still found in simple magnification devices, such as the magnifying glass, and the loupe.
Compound optical microscope
The compound microscope uses multiple lenses to further increase magnification. The diagram below shows a compound microscope. In its simplest form - as used by Robert Hooke - early compound microscope had a single glass objective lens of short focal length, and an ocular lens, or eyepiece. A simple mirror served as the source of reflected light.
Modern microscopes of this kind are usually more complex, with numerous lens components in both objective and eyepiece assemblies. These multi-component lenses are designed to reduce optical aberrations, particularly chromatic aberrations and spherical aberrations. Also, the mirror is replaced by a lamp unit, providing stable, controllable illumination.
History of the microscope
It is difficult to say who invented the compound microscope. Dutch spectacle-makers Hans Janssen and his son Zacharias Janssen are often said to have invented the first compound microscope in 1590, but this was a declaration made by Zacharias Janssen himself during the mid 1600s. The date is unlikely, as it has been shown that Zacharias Janssen actually was born around 1590. Another favorite for the title of 'inventor of the microscope' was Galileo Galilei. He developed an occhiolino or compound microscope with a convex and a concave lens in 1609. Galileo's microscope was celebrated in the ´Lynx academy´ founded by Federico Cesi in 1603.
Francesco Stelluti's drawing of three bees were part of pope Urban VIII´s seal, and count as the first microscopic figure published (see Stephen Jay Gould, The Lying stones of Marrakech, 2000). Christiaan Huygens, another Dutchman, developed a simple 2-lens ocular system in the late 1600s that was achromatically corrected, and therefore a huge step forward in microscope development. The Huygens ocular is still being produced to this day, but suffers from a small field size, and other minor problems.
Anton van Leeuwenhoek (1632-1723) is generally credited with bringing the microscope to the attention of biologists, even though simple magnifying lenses were already being produced in the 1500s. Van Leeuwenhoek's home-made microscopes were very small simple instruments, with a single, yet strong lens. They were awkward in use, but enabled van Leeuwenhoek to see detailed images. It took about 150 years of optical development before the compound microscope was able to provide the same quality image as van Leeuwenhoek's simple microscopes, due to timely difficulties of configuring multiple lenses. Still, despite widespread claims, van Leeuwenhoek is not the inventor of the microscope.
The components of the microscope
All optical microscopes share the same basic components:
The whole of the optical assembly is attached to a rigid arm which in turn is attached to a robust U shaped foot to provide the necessary rigidity. The arm is usually able to pivot on its joint with the foot to allow the viewing angle to be adjusted. Mounted on the arm are controls for focusing, typically a large knurled wheel to adjust coarse focus, together with a smaller knurled wheel to control fine focus.
On a standard compound optical microscope, there are three objective lenses: a scanning lens (4×), low power lens (10×)and high power lens (40×). Advanced microscopes often have a fourth objective lens, called an oil immersion lens. To use this lens, a drop of immersion oil is placed on top of the cover slip, and the lens is very carefully lowered until the front objective element is immersed in the oil film. Such immersion lenses are designed so that the refractive index of the oil and of the cover slip are closely matched so that the light is transmitted from the specimen to the outer face of the objective lens with minimal refraction. An oil immersion lens usually has a power of 100×.
The actual power or magnification of an optical microscope is the product of the powers of the ocular (eyepiece), usually about 10×, and the objective lens being used.
Compound optical microscopes can produce a magnified image of a specimen up to 1000× and, at high magnifications, are used to study thin specimens as they have a very limited depth of field.
How a microscope works
The optical components of a modern microscope are very complex and for a microscope to work well, the whole optical path has to be very accurately set up and controlled. Despite this, the basic optical principles of a microscope are quite simple.
The objective lens is, at its simplest, a very high powered magnifying glass i.e. a lens with a very short focal length. This is brought very close to the specimen being examined so that the light from the specimen comes to a focus about 160 mm inside the microscope tube. This creates an enlarged image of the subject. This image is inverted and can be seen by removing the eyepiece and placing a piece of tracing paper over the end of the tube. By careful focusing a rather dim image of the specimen, much enlarged can be seen. It is this real image that is viewed by the eyepiece lens that provides further enlargement.
In most microscopes, the eyepiece is a compound lens, which is made of two lenses, one near the front and one near the back of the eyepiece tube. This forms an air separated couplet. In many designs, the virtual image comes to a focus between the two lenses of the eyepiece, the first lens bringing the real image to a focus and the second lens enabling the eye to focus on the virtual image.
In all microscopes the image is viewed with the eyes focused at infinity (mind that the position of the eye in the above figure is determined by the eye's focus). Headaches and tired eyes after using a microscope are usually signs that the eye is being forced to focus at a close distance rather than at infinity.
The stereo or dissecting microscope is designed differently from the diagrams above, and serves a different purpose. It uses two separate optical paths with two objectives and two eyepieces to provide slightly different viewing angles to the left and right eyes. In this way it produces a three-dimensional (3-D) visualization of the sample being examined.
The stereo microscope is often used to study the surfaces of solid specimens or to carry out close work such as sorting, dissection, microsurgery, watch-making, small circuit board manufacture or inspection, and the like.
Great working distance and depth of field here are important qualities for this type of microscope. Both qualities are inversely correlated with resolution: the higher the resolution (i.e. the shorter the distance at which two adjacent points can be distinguished as separate), the smaller the depth of field and working distance. A stereo microscope has a useful magnification up to 100×. The resolution is maximally in the order of an average 10× objective in a compound microscope, and often much lower.
The stereo microscope should not be confused with a compound microscope equipped with binocular eyepieces. In such a microscope both eyes see the same image, but the binocular eyepieces provide greater viewing comfort. However, the image in such a microscope is no different from that obtained with a single monocular eyepiece.
Digital display with stereo microscopes
Recently various video dual CCD camera pickups have been fitted to stereo microscopes, allowing the images to be displayed on a high resolution LCD monitor. Software converts the two images to an integrated Anachrome 3D image, for viewing with plastic red/cyan glasses, or to the cross converged process for clear glasses and somewhat better color accuracy. The results are viewable by a group wearing the glasses. These files may recorded as well.
Other types of optical microscope include:
Limitations of light microscopes
Compound optical microscopes are limited in their ability to resolve fine details by the properties of light and the refractive materials used to manufacture lenses. A lens magnifies by bending light (see refraction). Optical microscopes are restricted in their ability to resolve features by a phenomenon called diffraction which, based on the numerical aperture (NA or AN) of the optical system and the wavelengths of light used (λ), sets a definite limit (d) to the optical resolution. Assuming that optical aberrations are negligible, the resolution (d) is given by:
Usually, a λ of 550 nm is assumed, corresponding to green light. With air as medium, the highest practical AN is 0.95, and with oil, up to 1.5.
Due to diffraction, even the best optical microscope is limited to a resolution of around 0.2 micrometres. Other optical microscope designs (e.g. Stimulated Emission Depletion Microscopy) can offer an improved resolution when observing self-luminous particles, which is not covered by Abbe's diffraction limit for the compound microscope. Abbe's theory (by Ernst Karl Abbe) is based on the fact that a non-self-luminous particle is illuminated by an extraneous source. For Ernst Abbe's work in light microscopy, see the Molecular Expressions web site at http://micro.magnet.fsu.edu/optics/timeline/people/abbe.html.
Connecting a digital camera to a light optical microscope
To capture digital microscope images with a digital SLR camera, the digital camera must be optically and mechanically adapted to the microscope. An adapter connects the camera with the microscope. A firm mechanical connection is particularly important, because even the smallest movements (vibrations) of the camera strongly reduce the image quality. Furthermore, the light path must be optically adapted so that a fully lit, focused image is projected to the camera sensor (CCD/CMOS). There are several methods for attaching a digital camera to a microscope. One solution is to use the phototube. Using the adapter, the digital camera is screwed firmly onto the tube. The two oculars continue to be used for the visual observation of the specimen. Unfortunately, almost all microscopes that are equipped with a phototube are very costly. For simple purposes, another option is to directly place a digital camera, without any adaptations, directly to the ocular, and to capture an image with a steady hand. Due to the lack of optical adaptation, however, this method produces a smaller, vignetted image in most cases. Vignettation means that the edges of an image are darker than the centre. This effect causes only a small part of the sensor to be optimally used; the rest remains black. A more professional, but also more costly solution is to use a tube adapter. With this method, the ocular is removed and an adapter is fitted into the phototube with the digital camera. The adapter acts as a mechanical and optical interface between microscope and digital camera. This makes it possible to avoid motion blurs due to camera shake and vignettation effects, leading to a much higher quality of the image.
Alternatives to optical microscopy
In order to overcome the limitations set by the diffraction limit of visible light other microscopes have been designed which use other waves.
The use of electrons and x-rays in place of light allows much higher resolution - the wavelength of the radiation is shorter so the diffraction limit is lower. To make the short-wavelength probe non-destructive, the atomic beam imaging system (atomic nanoscope) is proposed and widely discussed in the literature, but it is not yet competitive with conventional imaging systems.
|This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Optical_microscope". A list of authors is available in Wikipedia.|