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"magnetic field effect"¿¡ ´ëÇÑ °Ë»ö °á°úÀÔ´Ï´Ù. °Ë»ö °á°ú º¸´Â µµÁß¿¡ Tab ۸¦ ´©¸£½Ã¸é °Ë»ö âÀÌ ¼±Åõ˴ϴÙ.
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  • ¿µ¹®
    ÇѱÛ
  • magnetic domain
    Àڱⱸ¿ª
  • magnetic flux density
    ÀÚ±âÀ¯µ¿¹Ðµµ
  • magnetic gait
    ÀÚ¼®°ÉÀ½
  • magnetic induction
    ÀÚ±âÀ¯µµ
  • magnetic intensity
    ÀÚÀå°­µµ
  • magnetic isocenter
    ÀÚ±âµîÁß½É
  • magnetic memory
    ÀÚ±â(í¸Ñ¨)±â¾ï
  • magnetic moment nulling
    ÀÚ±â¸ð¸àÆ®¹«È¿È­
  • magnetic permeability
    ÀÚ±âÅõ°úµµ
  • magnetic pole
    ÀÚ±Ø, ÀÚ±â±Ø
  • magnetic resonance angiography
    ÀÚ±â°ø¸íÇ÷°üÃÔ¿µ(¼ú)
  • magnetic resonance functional neuroimaging
    ±â´ÉÀÚ±â°ø¸í³ú¿µ»ó
  • magnetic resonance image generation
    ÀÚ±â°ø¸í¿µ»ó»ý¼º
  • magnetic resonance imaging
    ÀÚ±â°ø¸í¿µ»ó
  • magnetic resonance mammography
    ÀÚ±â°ø¸íÀ¯¹æÃÔ¿µ(¼ú)
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  • ¿µ¹®
    ÇѱÛ
  • inhibitory effect
    ¾ïÁ¦È¿°ú
  • palliative effect
    ¿ÏÈ­È¿°ú, °æ°¨È¿°ú
  • prolonged effect
    Áö¼ÓÈ¿°ú
  • radiation effect
    ¹æ»ç¼±È¿°ú
  • reversing effect
    ¿ªÀüÈ¿°ú
  • shielding effect
    Â÷ÆóÈ¿°ú, °¡¸²È¿°ú
  • stochastic effect
    È®·ü·ÐÀûÈ¿°ú
  • synergistic effect
    »ó½ÂÈ¿°ú
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  • ¿µ¹®
    ÇѱÛ
  • magnetic coil
    ÀÚ±âÄÚÀÏ
  • magnetic transfer contrast
    ÀÚ±âÈ­Àü´Þ´ëÁ¶µµ, ÀÚ±âÈ­Àü´Þ´ëÁ¶µµ
  • magnetic dipole
    ÀÚ±â½Ö±ØÀÚ, ÀÚ¼º½Ö±ØÀÚ
  • magnetic domain
    Àڱ⿵¿ª, ÀÚ¼º¿µ¿ª
  • magnetic flux density
    ÀÚ±âÀ¯µ¿¹Ðµµ
  • magnetic electricity
    ÀÚ±âÀü±â
  • magnetic susceptibility proton relaxation enhancement
    ÀÚ±âÈ­À²¾ç¼ºÀÚÀÌ¿ÏÁõ°­
  • magnetic resonance image generation
    ÀÚ±â°ø¸í¿µ»ó»ý¼º
  • magnetic susceptibility gradient
    ÀÚ±âÈ­À²±â¿ï±â
  • magnetic induction
    ÀÚ±âÀ¯µµ
  • magnetic intensity
    ÀÚÀå°­µµ
  • magnetic isocenter
    Àڱ⵿½É
  • magnetic resonance imaging
    ÀÚ±â°ø¸í¿µ»ó
  • magnetic memory
    ÀÚ±â±â¾ï
  • magnetic permeability
    ÀÚ±âÅõ°úµµ
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  • ¿µ¹®
    ÇѱÛ
  • geometric field separtion
    ±âÇÏÇÐÀûÁ¶»ç¿µ¿ªºÐ¸®
  • geometrical field
    ±âÇÏÇÐÀûÁ¶»ç¿µ¿ª
  • gravitational field
    Áß·ÂÀå(ñìæ³íÞ).
  • high field MR scanner
    °íÀÚÀå ÀÚ±â°ø¸í½ºÄ³³Ê
  • illumination, dark-field
    ¾Ï½Ã¾ßÁ¶¸í
  • point outside field
    Á¶»ç¿µ¿ª¹ÛÁöÁ¡
  • pulsed-field gel electrophoresis (PFGE)
    °£Çæ¾ß Àü±â¿µµ¿
  • radio-frequency field
    °íÁÖÆÄ ÀÚÀå
  • rectangular field of view (FOV)
    Á÷»ç°¢Çü ½Ã¾ß
  • relative field
    ºñ±³¿µ¿ª(ÝïÎòçÐæ´).
  • Bernouilli effect
    º£¸£´©ÀÌ È¿°ú
  • Bohr effect
    º¸¾Æ È¿°ú(üùÍý)
  • CPE=£¾cytopathogenic effect
    ¼¼Æ÷º´º¯È¿°ú.
  • CPE=£¾cytopathogenic effect
    ¼¼Æ÷º´º¯È¿°ú.
  • Cytopath(ogen)ic effect, CPE
    ¼¼Æ÷º´º¯È¿°ú
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  • ¿µ¹®
    ÇѱÛ
  • electrocardiograpic gated magnetic resonance imaging
    ½ÉÀüµµ µ¿±â ÀÚ±â°ø¸í¿µ»ó
  • functional magnetic resonance imaging (fMRI)
    ±â´ÉÀû ÀÚ±â°ø¸í¿µ»ó
  • gradient magnetic coil
    °æ»ç ÀÚ±â ÄÚÀÏ
  • gradient echo technique magnetic susceptibility pro
    °æ»ç ¿¡ÄÚ¹ý ÀÚ±âÈ­À² ¾ç¼ºÀÚ ÀÌ¿Ï Áõ°­
  • gradient magnetic coil
    °æ»ç ÀÚ±â ÄÚÀÏ
  • magnetic bead
    Àڱⱸ½½
  • magnetic coil
    ÀÚ±â(ÀÚ¼º) ÄÚÀÏ
  • magnetic dipole
    ÀÚ±â(ÀÚ¼º) ½Ö±ØÀÚ
  • magnetic dipole moment
    Àڱ⠽ֱØÀÚ ¸ð¸àÆ®
  • magnetic disk
    Àڱ⠵ð½ºÅ©
  • magnetic domain
    ÀÚ±â(ÀÚ¼º) ¿µ¿ª
  • magnetic electricity
    ÀÚÀü±â(í¸ï³Ñ¨).
  • magnetic flux density
    ÀÚ±â À¯µ¿ ¹Ðµµ
  • magnetic induction
    ÀÚ±â À¯µµ
  • magnetic isocentre
    Àڱ⠵¿½É
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  • ¿µ¹®
    ÇѱÛ
  • proton magnetic reasonance
    ¾ç¼ºÀÚ ÀÚ±â°ø¸í(åÕàõí­àõí¸Ñ¨ÍìÙ°)
  • centrifugal field
    ¿ø½É·Â Àå(êÀãýÕôíÞ)
  • crystal field splitting
    °áÁ¤ ÀåºÐÇÒ(Ì¿ïÜíÞÝÂùÜ)
  • crystal field theory
    °áÁ¤ Àå·Ð(Ì¿ïÜíÞÖå)
  • electric field
    ÀüÀå(ï³íÞ) °ãÃþ(öµ)
  • field desorption mass spectrometry
    ÀåÅ»Âø Áú·®ºÐ±¤ÃøÁ¤¹ý (íÞ÷­ó·òõÕáÝÂÎÃö´ïÒÛö)
  • field flow fractionation
    Àå(íÞ)È帧 ºÐȹ¹ý(ÝÂüñÛö)
  • field inversion gel electrophoresis
    ÀåÀüµµ(íÞï´Óî) Á© Àü±â¿µµ¿(ï³Ñ¨ç¶ÔÑ)
  • field ionization mass spectrometry
    Àå(íÞ) ÀÌ¿ÂÈ­(ûù) Áú·®ºÐ±¤ÃøÁ¤¹ý(òõÕáÝÂÎÃö´ïÒÛö)
  • field ion microscope
    Àå(íÞ) À̿ Çö¹Ì°æ(úéÚ°Ìð)
  • ligand field theory
    ¸®°£µåÀå(íÞ) ÀÌ·Ð(ìµÖå)
  • pulsed-field gel electrophoresis
    ÆÞ½ºÀå(íÞ) Á© Àü±â¿µµ¿(ï³Ñ¨ç¶ÔÑ)
  • sedimentation field flow fractionation
    ħ°­Àå(öØË½íÞ) È帧ºÐȹ¹ý(ÝÂüñÛö)
  • anomeric effect
    ¾Æ³ë¸Ó¿µÇâ(ç¯úÂ)
  • asymmetry effect
    ºÎÀçÈ¿°ú(Üôî²üùÍý)
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  • ¿µ¹®
    ÇѱÛ
  • biological effect
    »ý¹°ÇÐÀûÈ¿°ú
  • cavitation effect
    °øµ¿È¿°ú
  • direct piezoelectric effect
    Á÷Á¢¾ÐÀüÈ¿°ú
  • Doppler effect
    µµÇ÷¯È¿°ú
  • effect
    È¿°ú, ÀÛ¿ë
  • entry slice effect
    À¯ÀԴܸéÈ¿°ú
  • fast scan effect
    °í¼Ó½ºÄµÈ¿°ú
  • Gibbs effect
    ±é½º È¿°ú
  • gradient echo effect
    °æ»ç¿¡ÄÚÈ¿°ú
  • gradient induced phase shift effect
    °æ»çÀ¯µµ À§»óº¯À§È¿°ú
  • halo effect
    ´Þ¹«¸®È¿°ú
  • immediate effect
    Áﰢȿ°ú, Áï½ÃÈ¿°ú
  • in-flow effect
    À¯ÀÔ È¿°ú
  • iron effect
    öȿ°ú
  • mach effect
    ¸¶ÇÏÇö»ó
KMLE ÀÇÇоà¾î »çÀü À¯»ç °Ë»ö °á°ú : 5 ÆäÀÌÁö: 2
IGFET insulated gate field effect transistor
JFET junction field effect transistor
MOSFET metal oxide semiconductor field effect transistor
MF magnetic field; meat free; medium frequency; megafarad; membrane filler; merthiolate-formaldehyde [s...
TVMF time varying magnetic field
KMLE ÀÚµ¿ÃßÃâ ÀÇÇоà¾î »çÀü À¯»ç °Ë»ö °á°ú : 5 ÆäÀÌÁö: 2
PEMF Pulsed Electro Magnetic Field
PMF Pulsed magnetic field
CMF constant magnetic field
ELF MF extremely low frequency magnetic field
SMF static magnetic field
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  • ¿µ¹®
    ÇѱÛ
    ¼³¸í
  • magnetic influence
    Àڱ⠰¨ÀÀ ÀÛ¿ë
  • magnetic isocentre
    Àڱ⠵¿½É
  • magnetic moment
    Àڱ⠸ð¸àÆ®
  • magnetic permeability
    ÀÚ±â Åõ°úµµ, ÀÚ±â Åõ°ú¼º
  • magnetic potential
    ÀÚ±â Æ÷ÅÙ¼È
  • magnetic quantum
    Àڱ⠾çÀÚ¼ö
  • magnetic resistance
    ÀÚ±â ÀúÇ×
  • magnetic resonance angiography
    Àڱ⠰ø¸í Ç÷°ü Á¶¿µ¼ú
  • magnetic resonance image generation
    Àڱ⠰ø¸í ¿µ»ó »ý¼º
  • magnetic resonance myelography
    Àڱ⠰ø¸í ô¼ö Á¶¿µ¼ú, Àڱ⠰ø¸í ô¼ö°­ Á¶¿µ¼ú
  • magnetic saturation
    ÀÚ±â Æ÷È­
  • magnetic stirrer
    ÀÚ¼® Á£°Ô, ÀÚ·Â ±³¹Ý±â
  • magnetic susceptibility artifact
    ÀÚ±âÈ­À² Àΰø¹°
  • magnetic susceptibility variation
    ÀÚ±âÈ­À² º¯ÀÌ
  • magnetic transfer contrast
    ÀÚÈ­ Àü´Þ ´ëÁ¶µµ
CancerWEB ¿µ¿µ ÀÇÇлçÀü À¯»ç °Ë»ö °á°ú : 15 ÆäÀÌÁö: 2
magnetic reconnection When a plasma has some resistivity, then the frozen-in flow requirement is relaxed (see frozen-in flow). In that case, the magnetic field can move through the plasma fluid on the resistive (magnetic diffusion) time scale. (Typically slow compared to magnetohydrodynamic timescales.) This allows field lines to reconnect with each other to change their topology in response to magnetic and other forces in the plasma. (see also Helicity, which is not conserved when reconnection is significant.) The predominant theory for solar flares is based on the transfer of energy from magnetic fields to plasma particles which can occur in reconnection. Reconnection can also be studied in the laboratory.
(09 Oct 1997)
magnetic resonance angiography Non-invasive method of vascular imaging and determination of internal anatomy without injection of contrast media or radiation exposure. The technique is used especially in cerebral angiography as well as for studies of other vascular structures.
(12 Dec 1998)
Magnetic Resonance Imaging A special imaging technique used to image internal stuctures of the body, particularly the soft tissues. An MRI image is often superior to a normal X-ray image.
It uses the influence of a large magnet to polarize hydrogen atoms in the tissues and then monitors the summation of the spinning energies within living cells.
Images are very clear and are particularly good for soft tissue, brain and spinal cord, joints and abdomen. These scans may be used for detecting some cancers or for following their progress.
Acronym: MRI
(11 Nov 1997)
magnetic resonance imaging, cine A type of imaging technique used primarily in the field of cardiology. By coordinating the fast gradient-echo mri sequence with retrospective ecg-gating, numerous short time frames evenly spaced in the cardiac cycle are produced. These images are laced together in a cinematic display so that wall motion of the ventricles, valve motion, and blood flow patterns in the heart and great vessels can be visualised.
(12 Dec 1998)
magnetic resonance scanning A special imaging technique used to image internal stuctures of the body, particularly the soft tissues. An MRI image is often superior to a normal X-ray image.
It uses the influence of a large magnet to polarize hydrogen atoms in the tissues and then monitors the summation of the spinning energies within living cells.
Images are very clear and are particularly good for soft tissue, brain and spinal cord, joints and abdomen. These scans may be used for detecting some cancers or for following their progress.
Acronym: MRI
(11 Nov 1997)
magnetic resonance spectroscopy Detection and measurement of the resonant spectra of molecular species in a tissue or sample.
(05 Mar 2000)
magnetic stress tensor <radiobiology> A second-rank tensor, proportional to the dyadic product of the magnetic field (B) with itself. The divergence of the magnetic stress tensor gives that part of the force which a magnetic field exerts on a unit volume of conducting fluid due to the curvature of the magnetic field lines.
(09 Oct 1997)
magnetic switching <radiobiology> The use as switches of saturable inductors for producing high power pulses without electrical arcs. This is a principal technology for extending single-shot accelerators in light-ion-beam-driven inertial confinement fusion to repetitively pulsed devices for possible reactors. Three terawatt, 200 KJ magnetic switches have been developed for fusion drivers at Sandia National Laboratories. (Info from the 1985 OSTI Glossary of Fusion Energy, may be out of date.)
(09 Oct 1997)
magnetic viscosity <physics> A magnetic field in a conducting fluid will damp fluid motions perpendicular to the field lines, similar to ordinary viscosity, even in the absence of sizeable mechanical forces or electric fields.
(09 Oct 1997)
nuclear magnetic resonance Spectroscopic method of measuring the magnetic moment of atomic nuclei in a covalent bond. Clinical application is in biochemical, metabolic, and physiologic studies of living tissue. It includes proton and electron spin-echo and spin-relaxation times.
(12 Dec 1998)
nuclear magnetic resonance, biomolecular Nmr spectroscopy on small- to medium-size biological macromolecules. This is often used for structural investigation of proteins and nucleic acids, and often involves more than one isotope.
(12 Dec 1998)
nuclear magnetic resonance imaging A special imaging technique used to image internal stuctures of the body, particularly the soft tissues. An MRI image is often superior to a normal X-ray image.
It uses the influence of a large magnet to polarize hydrogen atoms in the tissues and then monitors the summation of the spinning energies within living cells.
Images are very clear and are particularly good for soft tissue, brain and spinal cord, joints and abdomen. These scans may be used for detecting some cancers or for following their progress.
Acronym: MRI
(11 Nov 1997)
nuclear magnetic resonance tomography A special imaging technique used to image internal stuctures of the body, particularly the soft tissues. An MRI image is often superior to a normal X-ray image.
It uses the influence of a large magnet to polarize hydrogen atoms in the tissues and then monitors the summation of the spinning energies within living cells.
Images are very clear and are particularly good for soft tissue, brain and spinal cord, joints and abdomen. These scans may be used for detecting some cancers or for following their progress.
Acronym: MRI
(11 Nov 1997)
toroidal magnetic cusps A hybrid confinement scheme operating at high beta. A region of closed toroidal magnetic flux with high-beta plasma is separated by a narrow sheath from the surrounding field, which contains externally produced poloidal components arranged in a toroidal line-cusp configuration. Plasma migrating to the outer sheath is temporarily mirror-confined before being removed in a divertor system.
(09 Oct 1997)
lens, magnetic <microscopy> Circular electromagnets capable of projecting a precise circular magnetic field in a specified region. The field acts like an optical lens, having the same attributes (focal length angle of divergence etc.) and errors (spherical aberration, chromatic aberration, astigmatism etc.). They are used to focus and steer electrons in an Electron Microscope.
(05 Aug 1998)
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  • ¿µ¹®
    ÇѱÛ
  • halo effect
    Èı¤ÀÇ È¿°ú !
  • hothouse effect
    =greenhouse effect
  • inertia effect
    °ü¼ºÈ¿°ú !
  • key stone effect
    (È­¸éÀÇ) À§°¡ ÆÛÁö´Â Çö»ó
  • packing effect
    °áÇÕ È¿°ú !
  • photoelectric effect
    ±¤ÀüÈ¿°ú
  • ram effect
    ·¥ È¿°ú(±â¼Ó)ÀÇ Áõ°¡¿¡ µû¶ó ÈíÀÔ±¸¿¡ À¯ÀԵǴ °ø±âÀÇ ¾Ð·ÂÀÌ Áõ°¡ÇÏ´Â È¿°ú) '
  • ratchet effect
    ´Ü¼ÓÀû È¿°ú 
  • ripple effect
    ÆÄ±Þ È¿°ú !
  • shot effect,the
    (Áø°ø°üÀÇ À½±Ø¿¡¼­ ¹æ»çµÇ´Â ¿­ÀüÀÚÀÇ)»êź È¿°ú ''
  • side effect
    ºÎÀÛ¿ë
  • skin effect
    (Á֯ļö ÀüµµÃ¼ÀÇ)Ç¥ÇÇ È¿°ú
  • stage effect
    ¹«´ë È¿°ú
  • tunnel effect
    ÅͳΠȿ°ú !
  • magnetic
    ÀÚ±â
ÀÌ ¾Æ·¡ ºÎÅÍ´Â °á°ú°¡ ¾ø½À´Ï´Ù.
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    ¼ººÐ/ÇÔ·®
    ±¸ºÐ/º¸Çè±Þ¿©
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    ±¸ºÐ/º¸Çè±Þ¿©
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