Hering's Paradox

Hering's paradox describes a physical experiment in the field of electromagnetism that seems to contradict Maxwell's equation in general, and the Maxwell Faraday equation in particular.

The experiment is shown in the video on the right side. In the experiment, a slotted iron core is used, where a coil fed with a direct current generates a constant magnetic field in the core and in its slot.

Two different experiments are carried out in parallel:

*In the lower part, an ordinary conductor loop is passed through the slot of the iron core. As there is a magnetic field in this slot, a voltage is generated at the ends of the conductor loop, which is amplified and displayed in the lower oscilloscope image.

*A modified conductor loop is realized in the upper part. The conductor loop is split at one point and the split ends are fitted with a metal wheel. During the experiment, the metal wheels move around the magnetic core and exert a certain contact pressure on each other and on the core, respectively. As the magnetic core is electrically conductive, there is always an electrical connection between the wheels and therefore between the separated ends of the loop. The oscilloscope does not show any voltage despite the otherwise identical conditions as in the first experiment.

Paradox: In both experiments, the same change in magnetic flux occurs at the same time. However, the oscilloscope only shows a voltage in one experiment, although one would expect an induced voltage to be present in both experiments. This unexpected result is called Hering's paradox^[1][2][3][4], named after Carl Hering.

In the following, the experiment is viewed from a frame of reference in which the oscilloscope and the cables are at rest and an electrically conductive permanent magnet moves into a conductor loop at a speed of ${\displaystyle v}$. The upper and lower contact surfaces of the magnet are electrically connected to the conductor wires via fixed rollers.

The following electric field strengths result for the various sections of the conductor loop:

Section ${\displaystyle {\overline {AB}}}$ (conductor)	Section ${\displaystyle {\overline {BC}}}$ (magnet)	Section ${\displaystyle {\overline {CD}}}$ (conductor)	Section ${\displaystyle {\overline {DA}}}$ (oscilloscope)
${\displaystyle E=0}$	${\displaystyle {\vec {E}}=-{\vec {v}}\times {\vec {B}}=v\cdot B\cdot {\vec {e}}_{y}}$	${\displaystyle E=0}$	${\displaystyle E=0}$

An essential part of solving the paradox is the realization that the inside of the conductive moving magnet is not field-free, but that a non-zero electric field strength ${\displaystyle {\vec {E}}=-{\vec {v}}\times {\vec {B}}}$ prevails there. If this field strength is integrated along the line ${\displaystyle {\overline {BC}}}$, the result is the desired induced voltage. However, the induced voltage is not localized in the oscilloscope, but in the magnet.

The equation ${\displaystyle {\vec {E}}=-{\vec {v}}\times {\vec {B}}}$ can be derived from the consideration that there is obviously no current-driving force acting on any section of the circuit. Since the absence of forces also applies in particular to the inside of the magnet, the total electromagnetic force for a charge ${\displaystyle q}$ located inside the magnet can be assumed: ${\displaystyle {\vec {F}}_{q}=q\cdot ({\vec {E}}+{\vec {v}}_{q}\times {\vec {B}})={\vec {0}}}$. If we assume that the charge ${\displaystyle q}$ moves “slip-free” with the magnet (${\displaystyle {\vec {v}}_{q}={\vec {v}}}$), the following also applies: ${\displaystyle q\cdot ({\vec {E}}+{\vec {v}}\times {\vec {B}})={\vec {0}}}$. The last equation, however, is mathematically equivalent to ${\displaystyle {\vec {E}}=-{\vec {v}}\times {\vec {B}}}$.

To check whether the outcome of the experiment is compatible with Maxwell's equations, we first write down Faraday's law of induction in integral notation:

${\displaystyle \oint \limits _{\partial A}{\vec {E}}\cdot \mathrm {d} {\vec {s}}=-\!\!\iint \limits _{A}{\frac {\partial {\vec {B}}}{\partial t}}\cdot \mathrm {d} {\vec {A}}}$

Here ${\displaystyle A}$ is the induction surface, and ${\displaystyle \partial A}$ is its boundary curve, which is assumed to be composed of the (stationary) sections ${\displaystyle {\overline {AB}}}$, ${\displaystyle {\overline {BC}}}$, ${\displaystyle {\overline {CD}}}$ and ${\displaystyle {\overline {DA}}}$, respectively. The dot ${\displaystyle \cdot }$ indicates the dot product between two vectors. The direction of integration (clockwise) and the surface orientation (pointing into the screen) are right-handed to each other as assumed in Faraday's law.

Considering the electrical field strengths shown in the table, the left side of Faraday's law can be written as: ${\displaystyle \oint \limits _{\partial A}{\vec {E}}\cdot \mathrm {d} {\vec {s}}=\underbrace {\int \limits _{\mathrm {A} }^{\mathrm {B} }{\vec {E}}\cdot \mathrm {d} {\vec {s}}} _{=0}+\underbrace {\int \limits _{\mathrm {B} }^{\mathrm {C} }{\vec {E}}\cdot \mathrm {d} {\vec {s}}} _{=-v\cdot B\cdot L}+\underbrace {\int \limits _{\mathrm {C} }^{\mathrm {D} }{\vec {E}}\cdot \mathrm {d} {\vec {s}}} _{=0}+\underbrace {\int \limits _{\mathrm {D} }^{\mathrm {A} }{\vec {E}}\cdot \mathrm {d} {\vec {s}}} _{=0}=-v\cdot B\cdot L}$

To calculate the right-hand side of the equation, we imagine that within the time ${\displaystyle \mathrm {d} t}$ the magnetic field of the induction surface increases from ${\displaystyle 0}$ to ${\displaystyle B}$ (${\displaystyle \partial B=B}$) within a strip of length ${\displaystyle L}$ and width ${\displaystyle v\cdot \mathrm {d} t}$ (${\displaystyle \mathrm {d} A=L\cdot v\cdot \mathrm {d} t}$): Thus the right side of the equation equals

${\displaystyle -\iint \limits _{A}{\frac {\partial {\vec {B}}}{\partial t}}\cdot \mathrm {d} {\vec {A}}=-{\frac {B}{\mathrm {d} t}}\cdot L\cdot v\cdot \mathrm {d} t=-v\cdot B\cdot L}$

This shows that the outcome of Hering's paradox is in total agreement with Faraday's law.

It is worth noting that it does not matter whether the speed of the boundary curve corresponds to the speed of a conductor present at the same location, because a boundary curve is just an imaginary line without any physical properties. For reasons of simplicity, the boundary line was assumed to be constant in time in this experiment. The essential movement that takes place in the experiment is the movement of the magnet. The movement of the magnet is represented here specifically in the value of the electric field strength within the magnet, but not in the form of the underlying Maxwell equation.

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