Non-Coulomb Electric Field

Claimed by Geoffrey McKelvey

The non-Coulomb electric field, often represented by the variable [math]\displaystyle{ \vec{E}_{NC} }[/math], is an electric field, which does not result from a stationary point charge.

Magnetic Field- Induced Electric Field

The concept of the non-Coulomb electric field arises from the discovery of electric fields, which cannot be created as a result of Coulomb's law. Due to the involvement of motion, the resulting potential difference is often referred to as motional emf. The non-Coulomb electric field is also know as the curly electric field, due to it's directionality of curling around the conductor, which in turn will induce voltage, which in turn will induce the current to flow.

Lenz-Faraday Law

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While Faradays law tells us the magnitude of motional emf, which is equivalent to the change in magnetic flux over time, Lenz's law gives us the direction, and states that the direction of the motional emf can be found by [math]\displaystyle{ emf =- \frac{dB}{dt} }[/math], and the resultant induced electric field can be found by using the associated right-hand rule. This rule states that with the thumb of the right hand pointing in the direction of [math]\displaystyle{ -\frac{dB}{dt} }[/math], then the fingers will curl in the direction of the non-Coulomb electrical field. The combination of these two laws is known as the Lenz-Faraday law, and in its entirety appears as such [math]\displaystyle{ |emf| = \oint \vec{E}_{NC} \cdot \Delta \vec{l} = |\frac{d\Phi_{mag}}{dt}| }[/math]. These tell us that the flux of the time-varying magnetic field is what creates the non-Coulomb electric field, which is the source of voltage (emf) and ultimately, the induced current which follows.

A Mathematical Model

Along a closed path, the general equation, from which the magnitude of the non-Coulomb electric field can be obtained, is [math]\displaystyle{ |emf| = \oint \vec{E}_{NC} \cdot \Delta \vec{l} = |\frac{d\Phi_{mag}}{dt}| }[/math]. The direction of this can be found by using [math]\displaystyle{ emf =- \frac{dB}{dt} }[/math], followed by the used of the above integral in order to determine the direction of the field.

A Computational Model

In this vpython simulation, the effects of the motion of the magnet on a conductor can be observed, with the curly electric field shown in orange, while the induced magnetic field is shown in blue

In this vpython simulation, the curly magnetic field associated with the alternating magnetic field of a coil of wire can be seen, along with the measured induced current.

Examples

Be sure to show all steps in your solution and include diagrams whenever possible

Simple

Problem: On a circular path of radius 8 cm in air around a solenoid with increasing magnetic field, the emf is 32 volts. What is the magnitude of the non-Coulomb electric field on this path?

Solution: 1) We will use the equation [math]\displaystyle{ |emf| = |\oint \vec{E}_{NC} \cdot \Delta \vec{l}| }[/math]. As the electric field is constant, we are able to used [math]\displaystyle{ |emf| = \vec{E}_{NC} \cdot \Delta \vec{l} }[/math]

2) Now we plug in the variables which we have. The magnitude of the emf is known to be 32 V, and the radius of the coil is 0.08 m. Thus, the length of the path can be found by finding the circumference of the coil, which can be found by the equation 2πr, which gives a circumference of 0.5026 m.

3) Now that we have 2 of the 3 variables in our equation, we can then solve for the electric field by dividing the emf by the path length, which gives 63.66 V/m

A Little Harder

A wire of resistance 12 ohms and length 2.7 m is bent into a circle and is concentric with a solenoid in which the magnetic flux changes from 8 T·m2 to 5 T·m2 in 0.3 seconds. Find the emf, non-Coulomb electric field, and the induced current in the wire.

1) We will use the equations [math]\displaystyle{ |emf| = \oint \vec{E}_{NC} \cdot \Delta \vec{l} = |\frac{d\Phi_{mag}}{dt}| }[/math] along with [math]\displaystyle{ V = IR }[/math]

2)We know the path length is 2.7 m, the resistance is 12 Ω, and that the flux changes from 8 T·m2 to 5 T·m2 in 0.3 seconds, so [math]\displaystyle{ |\frac{(5-8)T·m^2 }{3 s}| }[/math]which via gives an emf of of 10 V

3) Knowing that the emf is 10 V, we can divide this by the length of the path, 2.7 m, for the magnitude of the NC electric field, which is 3.7 V/m.

4) Lastly, we are able to use the equation [math]\displaystyle{ V = IR }[/math] to solve for I. By dividing the voltage by the resistance, we find that the induced current measures 0.83 A

Connectedness

1. How is this topic connected to something that you are interested in?

Non-Coulomb electrical fields are a possible complication involved in magnetic resonance imaging (MRI), as they are what creates the induced voltage and ultimately, current, known as Eddy currents, , from the alternating magnetic fields that oppose the magnetic force that created them, which may cause such complications as heating tissue or creating an artifact within the image.

2. How is it connected to your major?

MRI and functional MRI (fMRI) are two very useful imaging techniques, being on of the highest resolution imaging techniques available, with none of the accompanying radiative dangers, which accompany computerized tomography (CT) scans. Eddy currents, product of the non-Coulomb fields, which accompany the induced, opposing magnetic field, present a significant complication to the use of MRI, via the creation of artifact within the image, heat within current loops induced in tissue, among others.

A step-by-step explanation of Eddy current can be found here

History

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In 1831, Heinrich Lenz, an Estonian physicist, for whom the symbol "L" of inductance is named, discovered the right-hand-rule relationship between a changing magnetic field and the direction of induced electric field, the non-Coulomb field.

This occurrence, however, was preceded by the discovery of the motional electromotive force (emf), resulting from interactions between a non-constant magnetic field and conductor, earlier in same year of 1931 by Michael Faraday, an English physicist and chemist. It is worth noting that this was discovered independently in 1932 by Joseph Henry, an American scientist, however Faraday published first, and is therefore credited with the discovery and contribution to science.

See also

Transformers (Circuits): This page investigates the use of these concepts in the transmission of electricity from power plants to the home.

External links

This video provides a video walkthrough of the process of motional emf form a time-varying magnetic field

References

Vpython Code Simulations, Written by Ruth Chabay and Bruce Sherwood, licensed under Creative Commons 4.0.