3. The magnetostatic Field

So far the magnetic field was defined quite pragmatically by the effect on a compass. For a deeper analysis of the magnetic field, the field is now to be considered again - as with the electric field - from two directions. The magnetic field will also be considered as a „causer field“ (a field caused by magnets) and an „acting field“ (field acting on a magnet). This chapter will first discuss the acting magnetic field. For this, it is convenient to consider the effects inside a toroidal coil (= donut-like setup). This can be seen in Abbildung 6. For reasons of symmetry, it is also clear here that the field lines form concentric circles.

In an experiment, a magnetic needle inside the toroidal coil is now to be aligned at perpendicular to the field lines. Then, the magnetic field will generate a torque $M$ which tries to align the magnetic needle in the field direction.

It now follows:

1. $M = const. \neq f(\varphi)$ : For the same distance from the axis of symmetry, the torque $M$ is independent of the angle $\phi$.
2. $M \sim I$ : The stronger the current flowing through a winding, the stronger the effect, i.e. the stronger the torque.
3. $M \sim N$ : The greater the number $N$ of windings, the stronger the torque $M$.
4. $M \sim {1 \over l}$ : The smaller the mean coil circumference $l$ the greater the torque. The mean coil circumference $l$ is equal to the average field line length.

To summarize: \begin{align*} M \sim {{I \cdot N}\over{l}} \end{align*}

The magnetic field strength $H$ inside the toroidal coil is given as: \begin{align*} \boxed{H ={{I \cdot N}\over{l}}} \quad \quad | \quad \text{applies to toroidal coil only} \end{align*}

For the unit of the magnetic field strength $H$ we get $[H] = {{[I]}\over{[l]}}= 1{{A}\over{m}}$

Magnetic Voltage

The cause of the magnetic field is the current in the winding of the coil. If this current $I$ and/or the number $N$ of windings is increased, the effect is amplified. To make this easier to handle, we introduce the Magnetic Voltage. The magnetic voltage $\theta$ is defined as

\begin{align*} \boxed{\theta = N \cdot I} \end{align*} The unit of $\theta$ is: $[\theta]= 1A$ (obsoletely called ampere-turn). For the magnetic voltage the currents which flow through the surface enclosed by the closed path have to be considered. A detailed definition will be given below after more analysis.

Thus, the magnetic field strength $H$ of the toroidal coil is then given by: $H= {{\theta}\over{l}}$

In the English literature often the name Magnetomotive Force $\mathcal{F}$ is used instead of magnetic potential difference $\theta$. The naming refers to the Electromotive Force, which depicts the ability of a voltage source to be able to drive a current in order to build a a defined voltage. Both „forces“ shall not be confused with the mechanical force $\vec{F}= m \cdot \vec{a}$, but only describe the driving cause behind the electric or magnetic fields. The German courses in higher semesters use the term „Magnetische Spannung“ - therefore, the English equivalent is introduced here.

magnetic Field Strength part 2: straight conductor

The previous derivation from the toroidal coil is now to be used to derive the field strength around a long, straight conductor. The magnetic voltage $\theta$ for a single conductor is given by $\theta = N \cdot I = 1 \cdot I = I$. For the toroidal coil, the magnetic field strength was given by the magnetic voltage $\theta$ divided by the (average) field line length. Because of the (same rotational) symmetry, this is also true for the single conductor.

The length of a field line around the conductor is given by the distance $r$ of the field line from the conductor: $l = l(r) = 2 \cdot \pi \cdot r$.
For the magnetic field strength of the single conductor we then get: \begin{align*} \boxed{H ={{\theta}\over{l}} = {{I}\over{2 \cdot \pi \cdot r}}} \quad \quad | \quad \text{applies only to the long, straight conductor} \end{align*}

In the electric field, the field line density was a measure of the strength of the field. This is also used for the magnetic field. Looking at the simulations in Falstad (e.g. Abbildung 8) with this understanding, one notices an inconsistency: contrary to the relationship just given, the field line density in the Falstad simulation not indicates the strength of the field. A realistic simulation is shown in Abbildung 9 for comparison, which makes the difference clear: the field is stronger near the conductor. Thus the field line density must also be stronger there.

magnetic Field Strength part 3: Generalization

So far, only rotationally symmetric problems could be solved. Now this shall be generalized. For this purpose we will have a look back to the electric field. For the electric field strength $E$ of a capacitor with two plates at a distance of $s$ and the potential difference $U$ holds:

\begin{align*} U = E \cdot s \quad \quad | \quad \text{applies to capacitor only} \end{align*}

This was extended to $U = \int_s E ds$. If we transform the formula for the magnetic field strength $H$ of a toroidal coil with the average field line length $l$ for comparison, we get

\begin{align*} \theta = H \cdot l \quad \quad | \quad \text{applies to toroidal coil only} \end{align*}

Can you see the similarities? Again, the magnitude of the field strength is multiplied by the length to arrive at another field-describing quantity (here, the magnetic voltage $\theta$). Because of the similarity - which continues below - the so-called magnetic potential difference $V_m$ is introduced:

\begin{align*} V_m = H \cdot s \quad \quad | \quad \text{applies to toroidal coil only} \end{align*}

Now what is the difference between the magnetic potential difference $V_m$ and the magnetic voltage $\theta$?

1. The first equation of the toroidal coil ($\theta = H \cdot l$) is valid for exactly one turn along a field line. In addition, the magnetic voltage is given by current and number of windings: $\theta = N \cdot I$.
2. The second equation ($V_m = H \cdot s$) holds independently of the path length $s$ along the field line. Only if $s = l$ is chosen, the magnetic voltage equals the magnetic potential difference. For the magnetic potential difference the $s$ can be a fraction or multiple of a single revolution $l$.

Thus, for each infinitesimally small path $ds$ along a field line, the resulting infinitesimally small magnetic potential difference $dV_m = H \cdot ds$ can be determined. If now along the field line the magnetic field strength $H = H(\vec{s})$ changes, then the magnetic potential difference from point $\vec{s_1}$ to point $\vec{s_2}$ results to:

\begin{align*} V_{m12} = V_m(\vec{s_1}, \vec{s_2}) = \int_\vec{s_1}^\vec{s_2} H(\vec{s}) ds \end{align*}

Up to now only the situation was considered that one always walks along the same field line. $\vec{s}$ therefore always arrived at the same field line. If one wants to extend this to arbitrary directions (also transverse to field lines), then only that part of the magnetic field strength $\vec{H}$ may be used in the formula, which is parallel to the path $d \vec{s}$. This is made possible by scalar multiplication. Thus, it is generally valid:

\begin{align*} \boxed{V_{m12} = \int_\vec{s_1}^\vec{s_2} \vec{H} \cdot d \vec{s}} \end{align*}

The magnetic voltage $\theta$ (and therefore the current) is the cause of the magnetic field strength. From the chapter the_stationary_electric_flow the general represenation of the current through a surface is known. This leads to the Ampere's Circuital Law

\begin{align*} \boxed{\int_{closed \\ path} \vec{H} \cdot d \vec{s} = \iint_{enclosed \\ surface \; A} \vec{S} d\vec{A} = \theta} \end{align*}

• The path integral of the magnetic field strength along an arbitrary closed path is equal to the free currents (= current density) through the surface enclosed by the path.
• The magnetic voltage $\theta$ can be gib
  • for a single conductor: $\theta = I$
  • for a coil: $\theta = N \cdot I$
  • for multiple conductors: $\theta = \sum_n \cdot I_n$
  • for spatial distribution: $\theta = \iint_{enclosed \\ surface \; A} \vec{S} d\vec{A}$
• $d\vec{s}$ and $d\vec{A}$ build a right-hand system: once the thumb of the right hand is pointing along $d\vec{A}$, the fingers of the right hand show the correct direction for $d\vec{s}$ for positive $\vec{H}$ and $\vec{S}$

Recap: Application of magn. Field Strength

The Ampere's Circuital Law shall be applied in order to find the magnetic strength $H$ inside the toroidal coil (Abbildung 13).

• The closed path $C$ is on revolution of a field line in the center of the coil
• the surface $A$ is the enclosed surface

This leads to:

\begin{align*} \int_C \vec{H} \cdot d \vec{s} &= \iint_{A} \vec{S} d\vec{A} = \theta \end{align*}

Since $\vec{H} \uparrow \uparrow d \vec{s}$ the term $\vec{H} \cdot d \vec{s}$ can be substituted by $H ds$:

\begin{align*} \int_C H \cdot ds &= \iint_{A} \vec{S} d\vec{A} \end{align*}

The magnetic voltage is the current through the surface and given as $N\cdot I$:

\begin{align*} \int_C H \cdot ds &= N\cdot I \end{align*}

The magnetic field strength $H$ can be considered constant:

\begin{align*} H \cdot \int_C ds &= N\cdot I \end{align*}

The average coil circumference is $2\pi \cdot {{d}\over{2}}$:

\begin{align*} H \cdot 2\pi \cdot {{d}\over{2}} &= N\cdot I \end{align*}

Therefore, the magnetic field strength in the toroidel coil is \begin{align*} H &= {{N\cdot I}\over{ \pi \cdot d }} \end{align*}

3.3 Ampere's Power Law, magnetic Flux Density

Please have a look at the contents (text, videos, exercises) on the page of the Magnetic Field on Wikipedia. Make sure that „Total“ is selected in the selection bar at the top. The last part on „Magnetic field with matter“ can be skipped - it will come in 2-3 terms.

\begin{align*} F = {{\mu _0}\over{2 \pi}} \cdot {{I_1 \cdot I_2 }\over{r}} \cdot l \end{align*}

With:

• Conductor length $l$
• distance between conductors $r$
• currents through the conductors $I_1$ and $I_2$
• vacuum permeability $\mu _0 = 4 \pi \cdot 10^{-7} {{Vs}\over{Am}}$

3.4 Lorentz Force

Video

Please have a look at the contents (text, videos, exercises) on the page of the KIT-Brückenkurs >> 4.2.3 Lorentz-Kraft. Make sure that „Total“ is selected in the selection bar at the top. The last part on „Magnetic field with matter“ can be skipped.

3.5 Matter in the magnetic field

3.6 Poynting Vector (not part of the curriculum)

• Clear picture of the Poynting vector along an electric circuit: https://de.cleanpng.com/png-jyy1vj/
• Good explanation of the Energy flow via a current model: http://amasci.com/elect/poynt/poynt.html
• Very detailed view of the energy flow in an electric circuit: http://sharif.edu/~aborji/25733/files/Energy%20transfer%20in%20electrical%20circuits.pdf

Force effect on dia- and paramagnetic materials in the magnetic field.

A living frog („diamagnet“) floats in a very strong magnetic field

Explanation of the hysteresis curve

Nice illustration of magnetization and demagnetization of soft magnetic material.

Wandering magnetic domains in a ferromagnetic material (from [email protected]).

Tasks

Task 1

References to the media used

Element	License	Link
Abbildung 21	CC-BY-SA 3.0	https://en.wikipedia.org/wiki/Magnetite?oldformat=true
Abbildung 2	Public Domain	https://commons.wikimedia.org/wiki/File:Magnetic_field_of_bar_magnets_attracting.png
Abbildung 10	CC-BY-SA 3.0	https://commons.wikimedia.org/wiki/File:VFPt_Solenoid_correct.svg