Magnetic Field - Yousef's Notes

As we did with the electric interaction, we shall decompose the magnetic interaction in two parts: 1) a moving charge (or current) generates a magnetic field in its surroundings and 2) another moving charge (or current) in its surroundings ‘feels’ the presence of the magnetic field as a force acting on it.

Let’s assume a test charge $q$ moving at velocity $\vec B$, the magnetic force follows the Lorentz law,

$$ \vec F=q \vec v \times \vec B $$ $$ \|\vec F\|=|q| \|\vec v\| \|\vec B\| sin\phi $$ Extension to a wire of length $l$ and current $I$, where $\vec l$ takes the direction of the the current density. $$ \vec{F}=I\vec{l} \times \vec{B} $$

Remarks

Like the electric field, the magnetic field is a vector field, which associates a vector to each point in space. $\vec B(\vec r): \mathbb{R}^3\rightarrow\mathbb{R}^3$.
when the charge moves in the same direction as the magnetic field, the force is zero.
the force is always perpendicular to the plane formed by the velocity and the magnetic field. Hence the work done by a magnetic force is zero. Invoking the work-energy theorem, a magnetic force cannot change the kinetic energy of a charge.
If two charges with equal magnitude and opposite sign move in the same field with the same velocity , the forces have equal magnitude but opposite direction.
The net force in the presence of both an electric and magnetic field is the vector sum: $\vec F=q (\vec E+\vec v \times \vec B)$.
SI units, 1 tesla $=1 \mathrm{T}=1 \mathrm{N} / (\mathrm{A} \cdot \mathrm{m})$. Also popular, 1 gauss $1 \mathrm{G}=10^{-4} \mathrm{T}$.
As for graphical representation purposes, a dot ($\cdot$) indicates a magnetic field vector directed out of the plane, whereas a cross ($\times$) represents a vector directed into the plane.

#Right Hand rule

![[Pasted image 20240306172453.png]]

#Magnetic Field Lines

The magnetic field is graphically represented by magnetic field lines. These are curves such that their tangent at any point align with the magnetic field. ![[Pasted image 20240306172525.png]] Properties:

their spacing represents the magnitude of the magnetic field: the closer the lines, the stronger the field.
At any given point the magnetic field is unique, hence field lines never intersect.
Magnetic field lines are not “lines of force”, this is, they do not point in the direction of the magnetic force on a charge.
Magnetic field lines do have the direction that a compass needle would point at each location https://youtu.be/1PuL-Zh8PPk

#Earth’s Magnetic Field

![[Pasted image 20240306172638.png]] The magnetic field of the Earth is of the order of 1G. 1T is actually a very intense magnetic field. Magnetic resonance imaging (MRI) employs strong magnetic fields $\approx 1.5 T$.

#Elementary Sources of Magnetic Field

#Magnetic Field of a Point Charge

Magnetic field of a charge located at $\vec r_1$ moving at velocity $\vec v$ ![[Pasted image 20240306172809.png]]

circuit element at origin	arbitrary origin

$$ \vec{B}(\vec r)=\frac{\mu_{0}}{4 \pi} \frac{q \vec{v} \times \hat{r}}{r^{2}} $$ $$ \hat r\equiv \vec r/r $$ | $$ \vec{B}\left(\vec{r}_{2}\right)=\frac{\mu_{0}}{4 \pi} \frac{q\vec v\times\left(\vec{r}_{2}-\vec{r}_{1}\right)}{\|\vec{r}_{2}-\vec{r}_{1}\|^{3}} $$

Similarly to the Coulomb field, the magnetic field is proportional to the charge q and the squared inverse of the distance $\propto 1/r^2$, but the direction is perpendicular to the plane formed by the velocity $\vec v$ and the field point $\vec r$.

#Magnetic Field of a Circuit Element

The total magnetic field created by several moving charges is the vector sum of the fields caused by the individual charges $d \vec{B}=\int d\vec B_{dQ}$. Hence it’s straightforward to derive the law of Biot and Savart

circuit element at origin	arbitrary origin

$$ d \vec{B}=\frac{\mu_{0}}{4 \pi} \frac{I d \vec{l} \times \hat{r}}{r^{2}} $$ | $$ d \vec{B}\left(\vec{r}_{2}\right)=\frac{\mu_{0}}{4 \pi} I_{1} \frac{d \vec{l} \times\left(\vec{r}_{2}-\vec{r}_{1}\right)}{\|\vec{r}_{2}-\vec{r}_{1}\|^{3}} $$

with $d\vec l$ being a vector with length $dl$ in the same direction as the current density in the conductor.

Integrating over the entire circuit

$$ \vec{B}\left(\vec{r}_{2}\right)=\frac{\mu_{0}}{4 \pi} I_{1} \oint_{1} \frac{d \vec{l}_{1} \times\left(\vec{r}_{2}-\vec{r}_{1}\right)}{\left|\vec{r}_{2}-\vec{r}_{1}\right|^{3}} $$

The field lines go in circles around $d\vec l$, with direction given by the right-hand side rule.

![[Pasted image 20240306204957.png]]	![[Pasted image 20240306205020.png]]

#Important Simple Cases

long straight conducting wire	on the axis of a circular loop
![[Pasted image 20240306205053.png]]	![[Pasted image 20240306205059.png]]
$B_{\theta}=\frac{\mu_{0} I}{2 \pi r}$	$B_{z}=\frac{\mu_{0} I a^{2}}{2\left(z^{2}+a^{2}\right)^{3 / 2}}$

Read and understand the derivation by yourself: Sears & Zemansky 28.3, 2

https://youtu.be/bq6IhapfucE

Solenoid: a helical winding of wire on a cylinder or toroid. When the solenoid is long compared to its cross-sectional diameter and the coils are tightly wound, the field inside the solenoid can be approximated by a uniform magnetic field, while the external field is almost negligible.

https://youtu.be/BbmocfETTFo

Long solenoid with n turns per unit length ![[Pasted image 20240306205221.png]]

$$ B=\frac{\mu_{0} N I}{2\pi r} $$

Toroidal solenoid with N turns ![[Pasted image 20240306205301.png]]

$$ B=\frac{\mu_{0} N I}{2\pi r} $$