gamma rays

Gamma rays

Electromagnetic radiation emitted from excited atomic nuclei as an integral part of the process whereby the nucleus rearranges itself into a state of lower excitation (that is, energy content). See Nuclear structure, Radioactivity

The gamma ray is an electromagnetic radiation pulse—a photon—of very short wavelength. The electric (E) and magnetic (H) fields associated with the individual radiations oscillate in planes mutually perpendicular to each other and also the direction of propagation with a frequency &ngr; which characterizes the energy of the radiation. The E and H fields exhibit various specified phase-and-amplitude relations, which define the character of the radiation as either electric (EL) or magnetic (ML). The second term in the designation indicates the order of the radiation as 2^L-pole, where the orders are monopole (2⁰), dipole (2¹), quadrupole (2²), and so on. The most common radiations are dipole and quadrupole. Gamma rays range in energy from a few kiloelectronvolts to 100 MeV, although most radiations are in the range 50–6000 keV. As such, they lie at the very upper high-frequency end of the family of electromagnetic radiations, which include also radio waves, light rays, and x-rays. See Electromagnetic radiation, Multipole radiation, Photon

The dual nature of gamma rays is well understood in terms of the wavelike and particlelike behavior of the radiations. For a gamma ray of intrinsic frequency &ngr;, the wavelength is λ = c/&ngr;, where c is the velocity of light; energy is E = h&ngr;, where h is Planck's constant. The photon has no rest mass or electric charge but, following the concept of mass-energy equivalence set forth by Einstein, has associated with it a momentum given by p = h&ngr;/c = E/c. See Light, Quantum mechanics, Relativity

Various nuclear species exhibit distinctly different nuclear configurations; the excited states, and thus the γ-rays which they produce, are also different. Precise measurements of the γ-ray energies resulting from nuclear decays may therefore be used to identify the γ-emitting nucleus. This has ramifications for nuclear research and also for a wide variety of more practical applications. One of the most useful studies of the nucleus involves the bombardment of target nuclei by energetic nuclear projectiles to form final nuclei in various excited states. Measurements of the decay γ-rays are routinely used to identify the various final nuclei according to their characteristic γ-rays.

In practical applications, the presence of γ-rays is used to detect the location or presence of radioactive atoms which have been deliberately introduced into the sample. In irradiation studies, for example, the sample is activated by placing it in the neutron flux from a reactor. The resultant γ-rays are identified according to isotope, and thus the composition of the original sample can be inferred. Such studies have been used to identify trace elements found as impurities in industrial production, or in ecological studies of the environment, such as minute quantities of tin or arsenic in plant and animal tissue.

In tracer studies, a small quantity of radioactive atoms is introduced into fluid systems (such as the human blood stream), and the flow rate and diffusion can be mapped out by following the radioactivity. Local concentrations, as in tumors, can also be determined.

For the three types of interaction with matter which together are responsible for the observable absorption of γ-rays, namely, Compton scattering, the photoelectric effect, and pair production, See Compton effect, Electron-positron pair production, Photoemission

gamma rays

(γ-rays) Very high energy electromagnetic radiation, i.e. radiation with the shortest wavelengths and the highest frequencies: γ-ray wavelengths are less than 10^–11 meters. There is no sharp cutoff between the γ-ray region and the adjacent X-ray region of the electromagnetic spectrum.

Gamma rays, like X-rays, are usually described in terms of photon energy, h ν, where ν is the frequency of the radiation and h is the Planck constant. The γ-ray region of the electromagnetic spectrum spans many decades of photon energy – from about 10⁵ electronvolts (eV) to more than 10¹⁵ eV. The range is customarily subdivided into a number of energy bands that are related to changes in telescope technology: low energy γ-rays, 10⁵–10⁷ eV;

medium energy γ-rays, 10⁷–10⁹ eV;

high energy γ-rays, 10⁹–10¹¹ eV;

very high energy γ-rays, 10¹¹–10¹⁴ eV;

ultra high energy γ-rays, >10¹⁴ eV.

Low energy γ-ray photons (h ν ˜ 10⁶ eV) are the most penetrating photons available to the astronomer. Traditionally γ-ray source spectra have been measured in units of photons per unit area per second per unit energy interval, i.e. treating the photons as individual events. At present the general move is to unify the measurement system by use of the jansky.

gamma rays

gamma

[gam´ah] the third letter of the Greek alphabet, γ, used in names of chemical compounds to distinguish one of three or more isomers or to indicate the position of substituting atoms or groups.gamma chain disease a type of heavy chain disease that resembles a malignant lymphoma, with symptoms of lymphadenopathy, hepatosplenomegaly, and recurrent infections.gamma globulin 1. a class of plasma proteins composed almost entirely of immunoglobulins, the proteins that function as antibodies. Production of gamma globulin may be increased in the body when there is invasion by harmful microorganisms. An abnormal amount in the blood, a condition known as hypergammaglobulinemia" >hypergammaglobulinemia, may be indicative of a chronic infection or certain malignant blood diseases. There is also a rare condition, agammaglobulinemia, in which the body is unable to produce gamma globulin; patients suffering from this are extremely susceptible to infection and must be given frequent injections of gamma globulin serum.2. immune globulin.gamma rays (γ-rays) electromagnetic emissions from radioactive substances; they are similar to and have the same general properties as x-rays but are produced through the disintegration of certain radioactive elements. They consist of high energy photons, have short wavelengths, and have no mass and no electric charge. Gamma rays are sometimes used in the treatment of deep-seated malignancies (see radiation therapy).

gam·ma rays

electromagnetic radiation emitted from radioactive substances; they are high-energy x-rays but originate from the nucleus rather than the orbital shell and are not deflected by a magnet.

gam·ma rays

(gamă rāz) Electromagnetic radiation emitted from radioactive substances; they are high-energy x-rays but originate from the nucleus rather than the orbital shell and are not deflected by a magnet.

Gamma rays

Short wavelength, high energy electromagnetic radiation emitted by radioactive substances.Mentioned in: Radiation Therapy

gam·ma rays

(gamă rāz) Electromagnetic radiation emitted from radioactive substances; high-energy x-rays that originate from the nucleus rather than the orbital shell and are not deflected by a magnet.

单词	gamma rays
释义	gamma rays gamma rays pl n (General Physics) streams of gamma radiation gamma rays Penetrating extreme shortwave radiation emitted in decay of some radioactive substances. Translations gamma rays Gamma rays Electromagnetic radiation emitted from excited atomic nuclei as an integral part of the process whereby the nucleus rearranges itself into a state of lower excitation (that is, energy content). See Nuclear structure, Radioactivity The gamma ray is an electromagnetic radiation pulse—a photon—of very short wavelength. The electric (E) and magnetic (H) fields associated with the individual radiations oscillate in planes mutually perpendicular to each other and also the direction of propagation with a frequency &ngr; which characterizes the energy of the radiation. The E and H fields exhibit various specified phase-and-amplitude relations, which define the character of the radiation as either electric (EL) or magnetic (ML). The second term in the designation indicates the order of the radiation as 2^L-pole, where the orders are monopole (2⁰), dipole (2¹), quadrupole (2²), and so on. The most common radiations are dipole and quadrupole. Gamma rays range in energy from a few kiloelectronvolts to 100 MeV, although most radiations are in the range 50–6000 keV. As such, they lie at the very upper high-frequency end of the family of electromagnetic radiations, which include also radio waves, light rays, and x-rays. See Electromagnetic radiation, Multipole radiation, Photon The dual nature of gamma rays is well understood in terms of the wavelike and particlelike behavior of the radiations. For a gamma ray of intrinsic frequency &ngr;, the wavelength is λ = c/&ngr;, where c is the velocity of light; energy is E = h&ngr;, where h is Planck's constant. The photon has no rest mass or electric charge but, following the concept of mass-energy equivalence set forth by Einstein, has associated with it a momentum given by p = h&ngr;/c = E/c. See Light, Quantum mechanics, Relativity Various nuclear species exhibit distinctly different nuclear configurations; the excited states, and thus the γ-rays which they produce, are also different. Precise measurements of the γ-ray energies resulting from nuclear decays may therefore be used to identify the γ-emitting nucleus. This has ramifications for nuclear research and also for a wide variety of more practical applications. One of the most useful studies of the nucleus involves the bombardment of target nuclei by energetic nuclear projectiles to form final nuclei in various excited states. Measurements of the decay γ-rays are routinely used to identify the various final nuclei according to their characteristic γ-rays. In practical applications, the presence of γ-rays is used to detect the location or presence of radioactive atoms which have been deliberately introduced into the sample. In irradiation studies, for example, the sample is activated by placing it in the neutron flux from a reactor. The resultant γ-rays are identified according to isotope, and thus the composition of the original sample can be inferred. Such studies have been used to identify trace elements found as impurities in industrial production, or in ecological studies of the environment, such as minute quantities of tin or arsenic in plant and animal tissue. In tracer studies, a small quantity of radioactive atoms is introduced into fluid systems (such as the human blood stream), and the flow rate and diffusion can be mapped out by following the radioactivity. Local concentrations, as in tumors, can also be determined. For the three types of interaction with matter which together are responsible for the observable absorption of γ-rays, namely, Compton scattering, the photoelectric effect, and pair production, See Compton effect, Electron-positron pair production, Photoemission gamma rays (γ-rays) Very high energy electromagnetic radiation, i.e. radiation with the shortest wavelengths and the highest frequencies: γ-ray wavelengths are less than 10^–11 meters. There is no sharp cutoff between the γ-ray region and the adjacent X-ray region of the electromagnetic spectrum. Gamma rays, like X-rays, are usually described in terms of photon energy, h ν, where ν is the frequency of the radiation and h is the Planck constant. The γ-ray region of the electromagnetic spectrum spans many decades of photon energy – from about 10⁵ electronvolts (eV) to more than 10¹⁵ eV. The range is customarily subdivided into a number of energy bands that are related to changes in telescope technology: low energy γ-rays, 10⁵–10⁷ eV; medium energy γ-rays, 10⁷–10⁹ eV; high energy γ-rays, 10⁹–10¹¹ eV; very high energy γ-rays, 10¹¹–10¹⁴ eV; ultra high energy γ-rays, >10¹⁴ eV. Low energy γ-ray photons (h ν ˜ 10⁶ eV) are the most penetrating photons available to the astronomer. Traditionally γ-ray source spectra have been measured in units of photons per unit area per second per unit energy interval, i.e. treating the photons as individual events. At present the general move is to unify the measurement system by use of the jansky. gamma rays gamma [gam´ah] the third letter of the Greek alphabet, γ, used in names of chemical compounds to distinguish one of three or more isomers or to indicate the position of substituting atoms or groups.gamma chain disease a type of heavy chain disease that resembles a malignant lymphoma, with symptoms of lymphadenopathy, hepatosplenomegaly, and recurrent infections.gamma globulin 1. a class of plasma proteins composed almost entirely of immunoglobulins, the proteins that function as antibodies. Production of gamma globulin may be increased in the body when there is invasion by harmful microorganisms. An abnormal amount in the blood, a condition known as hypergammaglobulinemia" >hypergammaglobulinemia, may be indicative of a chronic infection or certain malignant blood diseases. There is also a rare condition, agammaglobulinemia, in which the body is unable to produce gamma globulin; patients suffering from this are extremely susceptible to infection and must be given frequent injections of gamma globulin serum.2. immune globulin.gamma rays (γ-rays) electromagnetic emissions from radioactive substances; they are similar to and have the same general properties as x-rays but are produced through the disintegration of certain radioactive elements. They consist of high energy photons, have short wavelengths, and have no mass and no electric charge. Gamma rays are sometimes used in the treatment of deep-seated malignancies (see radiation therapy). gam·ma rays electromagnetic radiation emitted from radioactive substances; they are high-energy x-rays but originate from the nucleus rather than the orbital shell and are not deflected by a magnet. gam·ma rays (gamă rāz) Electromagnetic radiation emitted from radioactive substances; they are high-energy x-rays but originate from the nucleus rather than the orbital shell and are not deflected by a magnet. Gamma rays Short wavelength, high energy electromagnetic radiation emitted by radioactive substances.Mentioned in: Radiation Therapy gam·ma rays (gamă rāz) Electromagnetic radiation emitted from radioactive substances; high-energy x-rays that originate from the nucleus rather than the orbital shell and are not deflected by a magnet. FinancialSeeGammaThesaurusSeegamma ray
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