aligned magnetic field meydân-e meqnâtisi-ye âxatidé Fr.: champ magnétique aligné A magnetic field whose lines of force are oriented along a particular direction or by a particular manner (axially, vertically; randomly, properly, etc.) → aligned; → magnetic field. |
apparent field meydân-e padidâr Fr.: champ apparent The angular diameter of the circle of light that the eye sees through an eyepiece. |
azimuthal magnetic field meydân-e meqnâtisi-ye sugâni Fr.: champ magnétiquue azimutal In the → solar dynamo model, a magnetic field that points from east to west or vice-versa. |
circular magnetic field meydân-e meqnâtisi-ye dâyere-yi Fr.: champ magnétique circulaire A → magnetic field whose lines of force (→ line of force) run around the perimeter of the magnet. |
classical field theory negare-ye klâsik-e meydân Fr.: théorie classique des champs The theory that studies distributions of → energy, → matter, and other physical quantities under circumstances where their discrete nature is unimportant. Classical field theory traditionally includes → Newtonian mechanics, Maxwell's → electromagnetic theory, and Einstein's theory of → general relativity. The main scope of classical field theory is to construct the mathematical description of → dynamical systems with an infinite number of degrees of freedom. The word "classical" is used in contrast to those field theories that incorporate → quantum mechanics (→ quantum field theory). Classical field theories are usually categorized as → non-relativistic and → relativistic. |
coercive field meydân-e pazurandé Fr.: champ coercitif Same as → coercive force. |
conservative field meydân-e patâyešmand Fr.: champ conservatif A → field of → force in which the → work done in taking a particle from one point to another is independent of the → path taken between them. Examples are → electrostatic field and → gravitational field. → conservative; → field. |
crowded field meydân-e capirnâk Fr.: champ encombré An area on the sky where a large number of objects, commonly stars, are seen gathered together, usually as revealed by imaging. |
deep field meydân-e žarf Fr.: champ profond An area on the sky whose image is obtained with a deep exposure, such as → Hubble Deep Field. |
dipolar magnetic field meydân-e meqnâtisi-ye dipoli, ~ ~ diqotbi Fr.: champ magnétique dipolaire A → magnetic field produced by a system possessing a net magnetic → dipole moment. |
Draine field meydân-e Draine Fr.: champ de Draine A unit used to express the strength of → far ultraviolet (FUV) average → interstellar radiation field. It is equal to ~ 1.7 → Habing field. Named after B. T. Draine, 1978, ApJS 36, 595. |
Einstein's field equations hamugešhâ-ye meydân-e Einstein Fr.: équations de champ d'Einstein A system of ten non-linear → partial differential equations in the theory of → general relativity which relate the curvature of → space-time with the distribution of matter-energy. They have the form: G_{μν} = -κ T_{μν}, where G_{μν} is the → Einstein tensor (a function of the → metric tensor), κ is a coupling constant called the → Einstein gravitational constant, and T_{μν} is the → energy-momentum tensor. The field equations mean that the curvature of space-time is due to the distribution of mass-energy in space. A more general form of the field equations proposed by Einstein is: G_{μν} + Λg_{μν} = - κT_{μν}, where Λ is the → cosmological constant. Named after Albert Einstein (1879-1955); → field; → equation. |
electric field meydân-e barqi (#) Fr.: champ électrique The effect produced by the existence of an → electric charge in the volume of space that surrounds it. The direction of the field is taken to be the direction of the force it would exert on a positive test charge. The electric field is radially outward from a positive charge and radially in toward a negative point charge. |
electromagnetic field meydân-e barqâmeqnâti Fr.: champ électromagnétique A region of space consisting of coupled electric and magnetic lines of force at each point, generated by time-varying currents and accelerated charges. → electromagnetic; → field. |
electrostatic field meydân-e barqistâ (#) Fr.: champ électrostatique A region of space in which a non-moving → electric charge would be subjected to a force of attraction or repulsion as a result of the presence of another stationary electric charge. The electrostatic field is a special case of the → electromagnetic field. → electrostatic; → field. |
field meydân (#) Fr.: champ 1) General: An expanse of anything. M.E., from O.E. feld "plain, open land," probably related to O.E. folde "earth, land," from P.Gmc. *felthuz "flat land" (cf. Ger. Feld), from PIE *pel(e)-tu-,from base *pele- "flat, to sprea;" cf. L. planus "flat, level," → plane. Meydân "field, field of battle, arena, extensive plain," from Mid.Pers. mêdân "arena, field." This term is loaned into Ar. from Pers. or Mid.Pers. |
field curvature xamidegi-ye meydân (#) Fr.: courbure de champ An aberration in an optical instrument, common in Schmidt telescopes, in which the focus changes from the center to the edge of the field of view. Owing to this aberration, a straight object looks curved in the image. |
field equation hamugeš-e meydân Fr.: équation de champ In a physical theory, an equation that describe how a fundamental force interacts with matter. Einstein's equations of → general relativity are called field equations since they describe the → gravitational field. Similarly, → Maxwell's equations describe the electromagnetic field. |
field galaxy kahkešân-e meydân Fr.: galaxie de champ A galaxy that lies in the direction of a → cluster of galaxies, but is not a member of the cluster. Field galaxies are rare, less than about 5% of all galaxies. |
field horizontal branch star setâre-ye šâxe-ye ofoqi-ye meydâni Fr.: étoile de la branche horizontal du champ A → horizontal branch star with high velocity. → field; → horizontal; → branch; → star. |