Physics Using Geometric Algebra/Relativistic Classical Mechanics/The electromagnetic field: Difference between revisions

The electromagnetic field is defined in terms of the electric and magnetic fields as

${\displaystyle F=𝐄+ic𝐁.}$

Alternatively, the fields can be derived from a paravector potential ${\displaystyle A}$ as

${\displaystyle F=c{⟨\partial \overline{A}⟩}_{V+BV},}$

where:

${\displaystyle \partial =\frac{\partial }{\partial x^0}-\mathrm{\nabla }}$

and

${\displaystyle A=\varphi /c+𝐀.}$

The Lorenz gauge (without t) is expressed as

${\displaystyle ⟨\partial \overline{A}{⟩}_S=0}$

The electromagnetic field ${\displaystyle F}$ is still invariant under a gauge transformation

${\displaystyle A\to A^{\prime }=A+\partial \chi ,}$

where ${\displaystyle \chi }$ is a scalar function subject to the following condition

${\displaystyle \overline{\partial }\partial \chi =0}$

where

${\displaystyle \overline{\partial }=\frac{\partial }{\partial x^0}+\mathrm{\nabla }}$

The Maxwell equations can be expressed in a single equation

${\displaystyle \overline{\partial }F=\frac{1}{cϵ}\overline{j},}$

where the current ${\displaystyle j}$ is

${\displaystyle j=\rho c+𝐣}$

Decomposing in parts we have

• Real scalar: Gauss's Law
• Real vector: Ampere's Law
• Imaginary scalar: No magnetic monopoles
• Imaginary vector: Faraday's law of induction

The electromagnetic Lagrangian that gives the Maxwell equations is

${\displaystyle L=\frac{1}{2}⟨FF{⟩}_S-⟨A\overline{j}{⟩}_S}$

The energy density and Poynting vector can be extracted from

${\displaystyle \frac{{ϵ}_0}{2}F{F}^{†}=\epsilon +\frac{1}{c}S,}$

where energy density is

${\displaystyle \epsilon =\frac{{ϵ}_0}{2}(E^2+c^2{B}^2)}$

and the Poynting vector is

${\displaystyle S=\frac{1}{{\mu }_0}E\times B}$

The electromagnetic field plays the role of a spacetime rotation with

${\displaystyle \mathrm{\Omega }=\frac{e}{mc}F}$

The Lorentz force equation becomes

${\displaystyle \frac{dp}{d\tau }=⟨Fu{⟩}_V}$

or equivalently

${\displaystyle \frac{dp}{dt}=⟨F(1+v){⟩}_V}$

and the Lorentz force in spinor form is

${\displaystyle \frac{d\mathrm{\Lambda }}{d\tau }=\frac{e}{2mc}F\mathrm{\Lambda }}$

The Lagrangian that gives the Lorentz Force is

${\displaystyle \frac{1}{2}mu\overline{u}+e⟨\overline{A}u{⟩}_S}$

The propagation paravector is defined as

${\displaystyle k=\frac{\omega }{c}+𝐤,}$

which is a null paravector that can be written in terms of the unit vector ${\displaystyle 𝐤}$ as

${\displaystyle k=\frac{\omega }{c}(1+\widehat{𝐤}),}$

A vector potential that gives origin to a polarization|circularly polarized plane wave of left helicity is

${\displaystyle A=e^{is\widehat{𝐤}}𝐚,}$

where the phase is

${\displaystyle s={⟨k\overline{x}⟩}_S=\omega t-𝐤\cdot 𝐱}$

and ${\displaystyle 𝐚}$ is defined to be perpendicular to the propagation vector ${\displaystyle 𝐤}$. This paravector potential obeys the Lorenz gauge condition. The right helicity is obtained with the opposite sign of the phase

The electromagnetic field of this paravector potential is calculated as

${\displaystyle F=ick{A}_{},}$

which is nilpotent

${\displaystyle F{F}_{}=0}$

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