Motional Emf: Difference between revisions
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[[File:Middlemotionalemf.png|thumb|center|alt=Picture for middle level example]] | [[File:Middlemotionalemf.png|thumb|center|alt=Picture for middle level example]] | ||
''Taken from'' Matter & Interactions ''P64''. | ''Taken from the'' Matter & Interactions ''textbook, P64''. | ||
===Difficult=== | ===Difficult=== |
Revision as of 22:05, 4 December 2015
Claimed --Jli639 (talk) 14:50, 5 November 2015 (EST)
Motional emf is emf caused by motion in a magnetic field, leading to polarization. This is in contrast to how emf is generated in nature, namely through fluctuation of a magnetic field through a surface. Motional emf is difficult to observe visually using batteries, light bulbs, and compasses because it is so small.
The Main Idea
A metal bar moving through a magnetic field will polarize as a result of magnetic force, and the resulting charge separation, maintained by the magnetic force, is reminiscent of a battery. The polarized bar can then be used to generate an electric current in a circuit.
Additionally, as a result of the polarization, an electric field is also generated.
Polarization and Steady State
Polarization occurs due to the shift of the mobile electron sea in one direction. Eventually, the shifting will stop; enough electrons will shift in a particular direction so that the electric force, in the opposite direction, balances out the magnetic force ([math]\displaystyle{ qvB=qE }[/math]). Consequently, in the steady state, [math]\displaystyle{ E=vB }[/math] and there is no net force on the bar, so the bar does not require any additional force to keep it moving at a constant velocity.
In the steady state, a nonzero E-field exists inside the metal bar; however, if the bar is not connected in a circuit, there is no current. This is because the electric force is balanced with the magnetic force, resulting in zero net force on the mobile electrons. The potential difference across the metal bar is then the product of the electric field and the length of the bar.
Driving Current
If the metal bar is used to form a circuit, where the bar is slid along on two frictionless metal rails that are also connected, then the charge separation in the bar mimics a battery and can drive a current.
When the bar, in the described configuration, has a force applied to it and initially begins to move from rest, the entire lattice of positive ions is pulled in the direction of the bar's velocity. The mobile electrons are left behind for a brief moment, causing a near-instantaneous polarization in the bar, but are then pulled along with the positive ions due to the electric interaction between the charges.
Now that the bar, moving within the magnetic field, has a velocity, the direction of the magnetic force can be determined through the right-hand rule. The mobile electrons will be affected by both this magnetic force and the force being applied on the bar. Eventually, over time, the net force on the bar decreases to zero, and the bar moves at a constant speed, with a balance between the force pulling the bar and the component of magnetic force on the mobile electrons in the opposite direction. A current now runs through the bar. The mobile electrons in the bar move toward the negatively charged end, rather than the positively charged end, because the continuous depletion of charge means that the electric field is always slightly less than what is needed to balance out the opposing magnetic field. Therefore, the electrons move to the negative end to maintain charge separation and the electric field.
The potential difference across the bar is still the product of the electric field and the length of the bar. If the bar does have some resistance, then it is treated like a battery with internal resistance. In the circuit, the potential difference round-trip is zero.
A Mathematical Model
The potential difference across the metal bar is [math]\displaystyle{ \Delta V=emf=EL=v_{bar}BL }[/math]. If the bar has resistance, then [math]\displaystyle{ \Delta V=emf-r_{int}I }[/math].
When the bar in the circuit, in steady state, moves a distance [math]\displaystyle{ \Delta x }[/math] over a time [math]\displaystyle{ \Delta t }[/math], the work done is [math]\displaystyle{ F \Delta x }[/math] and the power supplied is [math]\displaystyle{ {F \Delta x}/{\Delta t} }[/math], or [math]\displaystyle{ Fv_{bar} }[/math]. If the rails in the circuit are connected by a resistor, then the power dissipated in the resistor is [math]\displaystyle{ ILBv_{bar}=I*emf={emf/R}*emf={emf^{2}}/R=RI^{2} }[/math].
Motional emf can be calculated in terms of magnetic flux: [math]\displaystyle{ \left | emf \right |=\left | \frac{\mathrm{d} \Phi_ {mag}}{\mathrm{d} t} \right | }[/math].
A Computational Model
A simulation of motional emf can be found here.
Examples
Be sure to show all steps in your solution and include diagrams whenever possible
Simple
Taken from the Matter & Interactions textbook, variation of P63.
A neutral metal rod of length 0.21 m slides horizontally at a constant speed of 7 m/s on frictionless insulating rails through a region of uniform magnetic field of magnitude 0.18 tesla, directed out of the page as shown in the diagram. (a) Is the top of the moving rod positive or negative? (b) After the initial transient, what is the magnitude of the net force on a mobile electron inside the rod? (c) What is the magnitude of the electric force on a mobile electron inside the rod? (d) What is the magnitude of the magnetic force on a mobile electron inside the rod? (e) What is the magnitude of the potential difference across the rod? (f) In what direction must you exert a force to keep the rod moving at constant speed?
(a) The top of the moving rod is negative. Use the right-hand rule.
(b) [math]\displaystyle{ \left | \overrightarrow{F}_{net} \right |=0 \: N }[/math] because after the initial transient the system is in steady state and the electric force balances out the magnetic force.
(c) First we recognize that the system is in steady state, so [math]\displaystyle{ E=vB=7 \times 0.18=1.26 }[/math]. Then [math]\displaystyle{ \left | \overrightarrow{F}_{E} \right |=\left | qE \right |=\left | -1.6 \times 10^{-19}(1.26) \right |=2.016 \times 10^{-19} \: N }[/math].
(d) In steady state, [math]\displaystyle{ \left | \overrightarrow{F}_{E} \right |=\left | \overrightarrow{F}_{B} \right | }[/math]. So, [math]\displaystyle{ \left | \overrightarrow{F}_{B} \right |=2.016 \times 10^{-19} \: N }[/math].
(e) [math]\displaystyle{ \Delta V=EL=v_{bar}BL=7 \times 0.18 \times 0.21=0.2646 \: V }[/math].
(f) No force is needed. The system is in steady state, so no additional force needs to be applied to keep the rod at constant speed.
Middling
Taken from the Matter & Interactions textbook, P64.
Difficult
Connectedness
The concept of power generated from a mechanical input is how electric generators function. The mechanical energy is commonly supplied by falling water at dams or expanding steam in turbines.
History
The phenomenon of electromagnetic induction, the emf produced from the interactions between a magnetic field and an electric circuit, was discovered independently in 1831 by Michael Faraday and 1832 by Joseph Henry (Faraday published his results first). Many of Faraday's ideas were rejected by the scientists of the day because they had no mathematical basis, but James Clerk Maxwell used these ideas to formulate his electromagnetic theory and Maxwell's equations.
At the time, it was not well understood how Maxwell's equations related to moving charged objects. J.J. Thomson was the first to attempt to derive, from Maxwell's equations, an equation describing effects on moving charged particles, and Oliver Heaviside built upon this work and fixed errors in Thomson's derivation. In 1892, Hendrik Lorentz finally derived the correct equation called the Lorentz force. The magnetic force component of the Lorentz force describes motional emf, as the magnetic force pushing electrons in the moving charged object induces the emf.
See also
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