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• Classical_interference_microscopy abstract "Classical interference microscopy (also referred to as quantitative interference microscopy) uses two separate light beams with much greater lateral separation than that used in phase contrast microscopy or in differential interference microscopy (DIC).In variants of the interference microscope where object and reference beam pass through the same objective, two images are produced of every object (one being the \"ghost image\"). The two images are separated either laterally within the visual field or at different focal planes, as determined by the optical principles employed. These two images can be a nuisance when they overlap, since they can severely affect the accuracy of mass thickness measurements. Rotation of the preparation may thus be necessary, as in the case of DIC.One of the first usable interference microscopes was designed by Dyson and manufactured by Cooke, Troughton & Simms (later Vickers Instruments), York England. This ingenious optical system achieved interference imaging without requiring polarizing elements in the beam path.A later popular design involving polarizing elements was designed by Smith and marketed first by C. Baker, London, and subsequently by the American Optical Company in USA.The double-image problem commonly encountered with all the above-mentioned designs was completely avoided in the Mach-Zehnder interferometer design implemented by Horn, a most expensive instrument, not employing polarized light, but requiring precisely-matched duplicated objectives and condensers. With this design (marketed by E. Leitz) 60 mm beam separation was achieved in microscopy but here the new difficulty has arisen of balancing optical thicknesses of two separate microscope slide preparations (sample and dummy) and maintaining this critical balance during longer observations (e.g. time-lapse studies of living cells maintained at 37 °C), otherwise a gradual change in background interference colour occurs over time.The main advantage offered by interference microscopy measurements is the possibility of measuring the projected dry mass of living cells, which was first effectively exploited by Andrew Huxley in studies of striated muscle cell structure and function, leading to the sliding filament model of muscle contraction.Interference microscopy became relatively popular in the 1940-1970 decades but fell into disuse because of the complexity of the instrument and difficulties in both its use and in the interpretation of image data. In recent years, however, the classical interference microscope (in particular the Mach-Zehnder instrument) has been \"rediscovered\" by biologists because its main original disadvantage (difficult interpretation of translated interference bands or complex coloured images) can now be easily surmounted by means of digital camera image recording, followed by the application of computer algorithms which rapidly deliver the processed data as false-colour images of projected dry mass. Examples of computer-assisted developments of the technique are found in the application of \"DRIMAPS\" from the laboratory of Graham Dunn and other recent developments of the methodology are described by Mahlmann et al. Interference microscopy for industrial inspection, semiconductor inspection and surface structure analysis is highly developed and in widespread use.".
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• Classical_interference_microscopy wikiPageLength "5750".
• Classical_interference_microscopy wikiPageOutDegree "7".
• Classical_interference_microscopy wikiPageRevisionID "663538971".
• Classical_interference_microscopy wikiPageWikiLink Category:Microscopy.
• Classical_interference_microscopy wikiPageWikiLink Cooke,_Troughton_&_Simms.
• Classical_interference_microscopy wikiPageWikiLink Differential_interference_contrast_microscopy.
• Classical_interference_microscopy wikiPageWikiLink Mach–Zehnder_interferometer.
• Classical_interference_microscopy wikiPageWikiLink Microscope_slide.
• Classical_interference_microscopy wikiPageWikiLink Phase-contrast_microscopy.
• Classical_interference_microscopy wikiPageWikiLink Time-lapse_photography.
• Classical_interference_microscopy wikiPageWikiLinkText "Classical interference microscopy".
• Classical_interference_microscopy wikiPageWikiLinkText "Smith/Baker".
• Classical_interference_microscopy wikiPageWikiLinkText "classical interference microscopy".
• Classical_interference_microscopy subject Category:Microscopy.
• Classical_interference_microscopy type Redirect.
• Classical_interference_microscopy type Technique.
• Classical_interference_microscopy comment "Classical interference microscopy (also referred to as quantitative interference microscopy) uses two separate light beams with much greater lateral separation than that used in phase contrast microscopy or in differential interference microscopy (DIC).In variants of the interference microscope where object and reference beam pass through the same objective, two images are produced of every object (one being the \"ghost image\").".
• Classical_interference_microscopy label "Classical interference microscopy".
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• Classical_interference_microscopy sameAs Q5128336.
• Classical_interference_microscopy wasDerivedFrom Classical_interference_microscopy?oldid=663538971.
• Classical_interference_microscopy isPrimaryTopicOf Classical_interference_microscopy.