Lecture Notes 18: Magnetic Monopoles/Magnetic Charges; Magnetic Flux Quantization, Dirac Quantization Condition, Coulomb/Lorentz Force Laws for Electric/Magnetic Charges, Duality Transformations
... Quantum mechanically, the e− behaves as a wave, not a point particle and thus the wavefunction ψ e ( re ) of the electron spreads out along its orbit as a periodic wave in such a way that an integer number of deBroglie wavelengths fit around the classical circumferential path, i.e. nλn = C = 2πρe wi ...
... Quantum mechanically, the e− behaves as a wave, not a point particle and thus the wavefunction ψ e ( re ) of the electron spreads out along its orbit as a periodic wave in such a way that an integer number of deBroglie wavelengths fit around the classical circumferential path, i.e. nλn = C = 2πρe wi ...
24.2 gauss`s law
... A spherical Gaussian surface surrounds a point charge q. Describe what happens to the total flux through the surface if (A) the charge is tripled, (B) the radius of the sphere is doubled, (C) the surface is changed to a cube, and (D) the charge is moved to another location inside the surface. ...
... A spherical Gaussian surface surrounds a point charge q. Describe what happens to the total flux through the surface if (A) the charge is tripled, (B) the radius of the sphere is doubled, (C) the surface is changed to a cube, and (D) the charge is moved to another location inside the surface. ...
investigation of measured distributions of local vector magnetic
... stator tooth. Additionally, from the root toward the top of the tooth, the rotating magnetic field trajectory shape was gradually changed from alternating field to rotating field. At the other top of the teeth, large rotating magnetic field was also observed. Figure 9 shows the measured magnetic flu ...
... stator tooth. Additionally, from the root toward the top of the tooth, the rotating magnetic field trajectory shape was gradually changed from alternating field to rotating field. At the other top of the teeth, large rotating magnetic field was also observed. Figure 9 shows the measured magnetic flu ...
Electric Motors
... opposites attract and like poles repel. So if you try to put two magnets together, south pole to south pole or north pole to north pole, they will push away from or repel one another. If you try to put a north pole close to the south pole of another magnet, the magnets will attract or move towards o ...
... opposites attract and like poles repel. So if you try to put two magnets together, south pole to south pole or north pole to north pole, they will push away from or repel one another. If you try to put a north pole close to the south pole of another magnet, the magnets will attract or move towards o ...
EM 3 Section 3: Gauss` Law 3. 1. Conductors and Insulators A
... r ∂r 3. 3. Examples of Gauss’s Law Griffiths 2.2.3 “Gauss’s law affords when symmetry permits by far the quickest and easiest way of computing electric fields”. Note well the qualifier when symmetry permits. Basically there are 3 kinds of symmetry which work and for which the following gaussian surf ...
... r ∂r 3. 3. Examples of Gauss’s Law Griffiths 2.2.3 “Gauss’s law affords when symmetry permits by far the quickest and easiest way of computing electric fields”. Note well the qualifier when symmetry permits. Basically there are 3 kinds of symmetry which work and for which the following gaussian surf ...
ELECTRIC AND MAGNETIC FIELDS
... in kilovolts (kV). Magnetic fields, measured in milliGauss (mG), only exist when an electric appliance is turned on – the higher the current, the greater the magnetic field.As with electric fields, the strength of a magnetic field dissipates dramatically as you move away from its source. However, un ...
... in kilovolts (kV). Magnetic fields, measured in milliGauss (mG), only exist when an electric appliance is turned on – the higher the current, the greater the magnetic field.As with electric fields, the strength of a magnetic field dissipates dramatically as you move away from its source. However, un ...
Topics - Wikispaces
... Labs are a prime part of the physics experience. For this reason we spend between one and two class periods a week involved in lab. Students are required to keep a bound notebook of their lab work. The format of labs will vary as necessary, but one of the primary formats that will be used is where t ...
... Labs are a prime part of the physics experience. For this reason we spend between one and two class periods a week involved in lab. Students are required to keep a bound notebook of their lab work. The format of labs will vary as necessary, but one of the primary formats that will be used is where t ...
Faraday paradox
This article describes the Faraday paradox in electromagnetism. There are many Faraday paradoxs in electrochemistry: see Faraday paradox (electrochemistry).The Faraday paradox (or Faraday's paradox) is any experiment in which Michael Faraday's law of electromagnetic induction appears to predict an incorrect result. The paradoxes fall into two classes:1. Faraday's law predicts that there will be zero EMF but there is a non-zero EMF.2. Faraday's law predicts that there will be a non-zero EMF but there is a zero EMF.Faraday deduced this law in 1831, after inventing the first electromagnetic generator or dynamo, but was never satisfied with his own explanation of the paradox.