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Electricity and magnetism

... A battery and an electric generator can both produce electricity. Which of the two uses chemical reactions to create an electric current ? a. b. ...

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Electricity and Magnetism

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...   Two charges, q1=0.1C and q2=5q1 (i.e.0.5C), are separated by a distance r=1m. Let F2 denotes the force on q2 (exerted by q1), and F1 denotes the force on q1 (exerted by q2). Which of the following relationship is true?   F1=5F2   F1=-5F2   F2=-5F1   F1=-F2 ...

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... Your thumb now points along the direction of the lines of flux inside the coil . . . towards the end of the solenoid that behaves like the N-pole of the bar magnet.  This right-hand grip rule can also be used for the flat coil. ...

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... Refuse to answer. Since the only way to know if you were right is to make a measurement, you no longer get "before the measurement". Therefore, it can not be tested. In 1964, Bell shown that it makes an observable difference if the particle has a precise (but unknown) position before measurement, wh ...

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... direction of the electric field is decided as if you had placed a small POSITIVE test charge wherever you are determining the electric field. Ask yourself which way it will move because of the other charge and that is the direction of the electric force AND E force and E field always point the same ...

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... product is positive. If and µ have no frequency dependence, electromagnetic stability requires > 0 and µ > 0, but if they are frequency-dependent, this condition becomes (ω)0 ≡ d(ω)/dω > 0 and (ωµ)0 ≡ d(ωµ)/dω > 0. This allows (ω) and µ(ω) to be negative at some frequencies, if they have stro ...

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... velocity v1=75 m/s up, and follows the dashed trajectory. ...

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Aharonov–Bohm effect

The Aharonov–Bohm effect, sometimes called the Ehrenberg–Siday–Aharonov–Bohm effect, is a quantum mechanical phenomenon in which an electrically charged particle is affected by an electromagnetic field (E, B), despite being confined to a region in which both the magnetic field B and electric field E are zero. The underlying mechanism is the coupling of the electromagnetic potential with the complex phase of a charged particle's wavefunction, and the Aharonov–Bohm effect is accordingly illustrated by interference experiments.The most commonly described case, sometimes called the Aharonov–Bohm solenoid effect, takes place when the wave function of a charged particle passing around a long solenoid experiences a phase shift as a result of the enclosed magnetic field, despite the magnetic field being negligible in the region through which the particle passes and the particle's wavefunction being negligible inside the solenoid. This phase shift has been observed experimentally. There are also magnetic Aharonov–Bohm effects on bound energies and scattering cross sections, but these cases have not been experimentally tested. An electric Aharonov–Bohm phenomenon was also predicted, in which a charged particle is affected by regions with different electrical potentials but zero electric field, but this has no experimental confirmation yet. A separate ""molecular"" Aharonov–Bohm effect was proposed for nuclear motion in multiply connected regions, but this has been argued to be a different kind of geometric phase as it is ""neither nonlocal nor topological"", depending only on local quantities along the nuclear path.Werner Ehrenberg and Raymond E. Siday first predicted the effect in 1949, and similar effects were later published by Yakir Aharonov and David Bohm in 1959. After publication of the 1959 paper, Bohm was informed of Ehrenberg and Siday's work, which was acknowledged and credited in Bohm and Aharonov's subsequent 1961 paper.Subsequently, the effect was confirmed experimentally by several authors; a general review can be found in Peshkin and Tonomura (1989).

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Aharonov–Bohm effect