x-ray microscope

Dictionary: x-ray microscope

n.
An instrument using x-rays to render a highly magnified image.

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A technique and an instrument or combination of instruments which utilize x-radiation for chemical analysis and for magnification of 100–1000 diameters. The resolution possible is about 0.25 micrometer. The contrast in the x-ray microscopic image is caused by the varying x-ray attenuation in the specimen. The advantage of x-ray microscopy is that it yields quantitative chemical information, besides structural information, about objects, including those which are opaque to light. It is a reliable ultramicrochemical analytical technique by which amounts of elements and weights of samples as small as 10⁻¹² to 10⁻¹⁴ g can be analyzed with an error of only a few percent. See also Microradiography.

There are four general principles of image formation in x-ray microscopy: (1) contact microradiography (illus. a), (2) projection x-ray microscopy (illus. b), (3) reflection x-ray microscopy (illus. c), and (4) x-ray image spectrography (illus. d).

In contact microradiography the thin specimen is placed in close contact with an extremely fine-grained photographic emulsion which has a resolution of more than 25, 000 lines/in. (1000 lines/mm), and radiographed with x-rays of suitable wavelength. Thus an absorption image in scale 1:1 is obtained, and this image is subsequently viewed in a light microscope. The maximal resolution is that of the optical microscope (0.25 μm), but the image has more information, which can be obtained by examining the microradiogram in the electron microscopes. See also Electron microscope.

Principles for x-ray microscopy. (a) Contact microradiography; (b) projection x-ray microscopy; (c) reflection x-ray microscopy; and (d) x-ray image spectrography.

Projection x-ray microscopy, or x-ray shadow microscopy, is based on the possibility of producing an extremely fine x-ray focal spot. This is achieved by an electronic lens system similar to that in the electron microscope. The fine focal spot is produced on a very thin metal foil which serves as a transmission target. The x-rays are generated on the target by the impact of the electrons. The sample is placed near the target, and the primary magnification depends on the ratios of the distances from focal spot to sample and sample to film. Resolution is of the same order as the size of the focal spot; the best value is about 0.1 μm in favorable objects.

The method of reflection x-ray microscopy is based on the fact that the refractive index for x-rays in solids is a very small amount less than 1. Thus at grazing incidence (that is, incidence at very small angles), the x-rays are totally reflected, and if the reflecting surface is made cylindrical, there will be a focusing action in one dimension. By crossing two such surfaces a true image formation can be obtained, although with some astigmatism, which can be corrected by giving the surfaces a complicated optical shape. The resolution by this procedure is about 0.5–1μm.

X-ray image spectrography utilizes Bragg reflections in a cylindrically bent crystal and produces slightly enlarged emission images; this technique is best classified as a micromodification of x-ray fluorescence analysis. The resolution is about 50 μm. See also X-ray diffraction; X-ray fluorescence analysis.

In biology, x-ray microscopy has been utilized for the quantitative determination of the dry weight, water content, and elementary composition of many tissues, especially mineralized tissues.

Medical Dictionary: x-ray microscope

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An instrument using x-rays to render a highly magnified image.

Wikipedia: X-ray microscope

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An X-ray microscope uses electromagnetic radiation in the soft X-ray band to produce images of very small objects.

Unlike visible light, X-rays do not reflect or refract easily, and they are invisible to the human eye. Therefore the basic process of an X-ray microscope is to expose film or use a charge-coupled device (CCD) detector to detect X-rays that pass through the specimen. It is a contrast imaging technology using the difference in absorption of soft x-ray in the water window region (wavelength region: 2.3 - 4.4 nm, photon energy region: 0.28 - 0.53 keV) by the carbon atom (main element composing the living cell) and the oxygen atom (main element for water).

Early X-ray microscopes by Paul Kirkpatrick and Albert Baez used grazing-incidence reflective optics to focus the X-rays, which grazed X-rays off parabolic curved mirrors at a very high angle of incidence. An alternative method of focusing X-rays is to use a tiny fresnel zone plate of concentric gold or nickel rings on a silicon dioxide substrate. Sir Lawrence Bragg produced some of the first usable X-ray images with his apparatus in the late 1940's.

Indirect drive laser inertial confinement fusion uses a "hohlraum" which is irradiated with laser beam cones from either side on it its inner surface to bathe a fusion microcapsule inside with smooth high intensity X-rays. The highest energy X-rays which penetrate the hohlraum can be visualized using an X-ray microscope such as here, where X-radiation is represented in orange/red.

In the 1950's Newberry produced a shadow X-ray microscope which placed the specimen between the source and a target plate, this became the basis for the first commercial X-ray microscopes from the General Electric Company.

The Advanced Light Source (ALS)[1] in Berkeley CA is home to XM-1 (http://www.cxro.lbl.gov/BL612/), a full field soft X-ray microscope operated by the Center for X-ray Optics [2] and dedicated to various applications in modern nanoscience, such as nanomagnetic materials, environmental and materials sciences and biology. XM-1 uses an X-ray lens to focus X-rays on a CCD, in a manner similar to an optical microscope. XM-1 still holds the world record in spatial resolution with Fresnel zone plates down to 15nm and is able to combine high spatial resolution with a sub-100ps time resolution to study e.g. ultrafast spin dynamics.

The ALS is also home to the world's first soft x-ray microscope designed for biological and biomedical research. This new instrument, XM-2 was designed and built by scientists from the National Center for X-ray Tomography (http://ncxt.lbl.gov). XM-2 is capable of producing 3-Dimensional tomograms of cells.

Sources of soft X-rays suitable for microscopy, such as synchrotron radiation sources, have fairly low brightness of the required wavelengths, so an alternative method of image formation is scanning transmission soft X-ray microscopy. Here the X-rays are focused to a point and the sample is mechanically scanned through the produced focal spot. At each point the transmitted X-rays are recorded with a detector such as a proportional counter or an avalanche photodiode. This type of Scanning Transmission X-ray Microscope (STXM) was first developed by researchers at Stony Brook University and was employed at the National Synchrotron Light Source at Brookhaven National Laboratory.

The resolution of X-ray microscopy lies between that of the optical microscope and the electron microscope. It has an advantage over conventional electron microscopy in that it can view biological samples in their natural state. Electron microscopy is widely used to obtain images with nanometer level resolution but the relatively thick living cell cannot be observed as the sample has to be chemically fixed, dehydrated, embedded in resin, then sliced ultra thin. However, it should be mentioned that cryo-electron microscopy allows the observation of biological specimens in their hydrated natural state. Until now, resolutions of 30 nanometer are possible using the Fresnel zone plate lens which forms the image using the soft x-rays emitted from a synchrotron. Recently, more researchers have begun to use the soft x-rays emitted from laser-produced plasma rather than synchrotron radiation.

Additionally, X-rays cause fluorescence in most materials, and these emissions can be analyzed to determine the chemical elements of an imaged object. Another use is to generate diffraction patterns, a process used in X-ray crystallography. By analyzing the internal reflections of a diffraction pattern (usually with a computer program), the three-dimensional structure of a crystal can be determined down to the placement of individual atoms within its molecules. X-ray microscopes are sometimes used for these analyses because the samples are too small to be analyzed in any other way.

A square beryllium foil mounted in a steel case to be used as a window between a vacuum chamber and an X-ray microscope. Beryllium, due to its low Z number is highly transparent to X-rays.

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	projection microscope (physics)
	microradiogram (physics)
	Historadiography

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