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  • ¿µ¹®
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  • valence electron
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  • noncyclic electron flow
    ºñȸ·ÎÀüÀÚÀü´Þ
  • scanning electron microscope
    ½ºÄ³´×ÀüÀÚÇö¹Ì°æ
  • transmission electron microscope
    Åõ°úÀüÀÚÇö¹Ì°æ
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  • ¿µ¹®
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  • electron emission
    ÀüÀÚ¹æÃâ
  • electron emission
    ÀüÀÚ¹æÃâ(ï³í­Û¯õó).
  • electron equilibrium
    ÀüÀÚÆòÇü
  • electron fluence
    ÀüÀÚÇ÷ç¾ð½º
  • electron gun
    ÀüÀÚÃÑ
  • electron hole
    ÀüÀÚ±¸¸Û.
  • electron interrupter
    ÀüÀÚÂ÷´Ü±â(¡­ó´Ó¨Ðï).
  • electron microscope
    ÀüÀÚÇö¹Ì°æ
  • electron microscope
    ÀüÀÚÇö¹Ì°æ.
  • electron microscope, analytical
    ºÐ¼®¿ë ÀüÀÚÇö¹Ì°æ
  • electron microscope, immune
    ¸é¿ªÀüÀÚÇö¹Ì°æ
  • electron microscope, scanning
    ÁÖ»çÀüÀÚÇö¹Ì°æ
  • electron microscope, transmission
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  • electron microscopic autoradiography
    µ¿À§¿ø¼ÒÇ¥Áö ÀüÀÚÇö¹Ì°æ¹ý
  • electron microscopic radioautography
    ÀüÇö¹æ»ç¼±ÀÚ°¡±â·Ï¹ý, ÀüÇöÀÚ±â¹ý.
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  • electron transport chain
    ÀüÀÚ¼ö¼Û(ï³í­âÃáê) »ç½½
  • electron transport particle
    ÀüÀÚ¼ö¼Û ÀÔÀÚ(ï³í­âÃáêØ£í­)
  • electron transport system
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  • electron trap
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  • hydrated electron
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  • internal conversion electron
    ³»ºÎÀüȯ ÀüÀÚ(Үݻï®üµï³í­)
  • low-energy electron diffraction
    Àú(î¸)¿¡³ÊÁö ÀüÀÚȸÀý(ï³í­üÞï¹)
  • negative electron
    À½ÀüÀÚ(ëäï³í­)
  • odd electron
    Ȧ ÀüÀÚ(ï³í­)
  • orbital electron capture
    ±ËµµÀüÀÚ Æ÷ȹ(ÏùÔ³ï³í­øÙüò)
  • photosynthetic electron transport
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  • positive electron
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  • scanning electron microscope
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  • secondary electron
    ÀÌÂ÷ ÀüÀÚ(ì£ó­ï³í­)
  • transmission electron microscope
    Åõ°ú ÀüÀÚ Çö¹Ì°æ(÷âΦï³í­úéÚ°Ìð)
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ATEM analytic transmission electron microscopy
BEI back-scattered electron imaging; biological exposure indexes; butanol-extractable iodine
BeV, Bev billion electron volts
CEM computerized electroencephalographic map; conventional transmission electron microscope
CIDEP chemically induced dynamic electron polarization
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EBT Electron Beam Tomography
EELS Electron Energy Loss Spectroscopy
EI Electron Impact
EM Electron Microscopic
ENDOR Electron Nuclear DOuble Resonance
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  • recoil electron
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  • scanning electron micrograph
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  • scanning electron microscopy
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  • transmission electron microscopic
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  • valence electron
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secondary electron imaging <microscopy> Production of secondary electrons is very topography related. Due to their low energy, 5eV, only secondaries that are very near the surface (less than 10nm) can exit the sample and be examined. Any changes in topography in the sample that are larger than this sampling depth will change the yield of secondaries due to collection efficiencies. Collection of these electrons is aided by using a collector in conjunction with the secondary electron detector. The collector is a grid or mesh with a +100V potential applied to it which is placed in front of the detector, attracting the negatively charged secondary electrons to it which then pass through the grid-holes and into the detector to be counted. When a Secondary Electrons collide with the solid-state saemiconductor detector an electron-hole pairs are created which are then counted. This quantity is translated into a pixel intensity and displayed on the CRT, forming the image.
(05 Aug 1998)
Selected Area Electron Diffraction <technique> In this diffraction mode an aperture is used to define the area from which a diffraction pattern is to be recorded from a thin sample. This aperture is typically located in an image plane below the sample.
Selected Area Electron Diffraction patterns are simple spot patterns and are of use in phase determination (lattice spacing measurement) and defect analysis (sample orientation).
Acronym: SAED
(05 Aug 1998)
immune electron microscopy Electron microscopy of biological specimens to which specific antibody has been bound.
(05 Mar 2000)
internal conversion electron An electron, similar to an Auger electron, released from one of the electron orbits of the atom upon activation by a gamma-ray from that atom's nucleus; the electron has kinetic energy equal to the net energy transition of the disintegration.
(05 Mar 2000)
electron <chemistry, physics> A stable atomic particle that has a negative charge, the flow ofelectrons through a substance constitutes electricity.
(19 Jan 1998)
electron beam <microscopy> A stream of electrons in an electron optical system.
(05 Aug 1998)
electron capture <radiobiology> Nuclear decay process whereby a proton in the nucleus absorbs an orbiting electron and converts to a neutron.
(09 Oct 1997)
electron carrier <chemistry> A protein which can either accept or donate electrons in oxidation-reduction reactions.
(19 Jan 1998)
Electron Channeling Pattern <microscopy> A pattern formed by the periodic backscattering of electrons by the specimen lattice in a transmission electron microscope. Allows determination of crystal structure and lattice parameters in crystals greater than 10 micrometres diameter.
Acronym: ECP
(05 Aug 1998)
electron cyclotron discharge cleaning Using relatively low power microwaves (at the electron cyclotron frequency) to create a weakly ionised, essentially unconfined hydrogen plasma in the vacuum chamber.
The ions react with impurities on the walls of the tokamak and help remove them from the chamber. For instance, Alcator C-mod typically applies electron cyclotron discharge cleaning for a few days prior to beginning a campaign, and a few hours before each day's run.
(09 Oct 1997)
electron cyclotron emission <physics, radiobiology> As electrons gyrate around in a magnetic field (see also larmor radius or cyclotron radius), they radiate radio-frequency electromagnetic waves. This is known as electron cyclotron emission, and can be measured to help diagnose a plasma.
(09 Oct 1997)
electron cyclotron heating <physics, radiobiology> Radiofrequency heating scheme that works by injecting electromagnetic wave energy at the electron cyclotron gyration frequency.
The electric field of the electromagnetic wave at this frequency looks to a gyrating electron like a static electric field, and thus causes large acceleration of the electron (larger than if the frequency were off the cyclotron frequency and thus, to the electron, appearing to change direction as a function of time).
The accelerated electron gains energy, which is then shared with other particles through collisions, resulting in heating. Higher harmonics (multiples) of the cyclotron frequency can also be used in principle.
(09 Oct 1997)
electron diffraction <technique> The phenomenon, or technique of producing diffraction patterns through the incidence of electrons upon matter.
(05 Aug 1998)
electron donor A molecule or compound that gives up electrons in an oxidation-reduction reaction.
(09 Oct 1997)
electron gun <apparatus> A cathode/anode device intended to produce a stream of electrons. Also used inside a video camera tube and monitor picture tube that contains a heated cathode. Electrons emitted by the gun are focused to produce the scanning beam.
(05 Aug 1998)
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