Translation:On the spacetime lines of a Minkowski world/Paragraph 3

Template:Translation header

The considerations shall now be based on Template:Sc's ${\displaystyle S_4}$, the “world”, ${\displaystyle S_4(xyzict)}$:

Template:Center

With

Template:Center

the Maxwell quadrupels become in orthogonal Cartesian coordinates Template:Pagenum

Template:Center

Template:Center

where

Template:Center

and

Template:Center

If we treat ${\displaystyle F}$ as covariant, then this is evidently somewhat arbitrary in terms of Cartesian orthogonal coordinates, since covariants and contravariantes coincide here. If we would require (following Template:Sc) that the ${\displaystyle F}$ transform like the products of the corresponding components of the radius vector, then we would have to postulate the ${\displaystyle F}$ as contravariants. By passage to the reciprocal system we can, however, represent them as convariants. For the sake of being easier related to the integral forms, we stick to the covariant description.

Now, these two quadruple are the coefficients of two mutually dual integral forms.^[1] Thus we write, still in Cartesian coordinates,

Template:Center

Of course, ${\displaystyle \mathrm{P}}$ satisfies the continuity equations, because (see § 1):

Template:Center

Template:Pagenum The disappearance of the ${\displaystyle {\mathrm{F}}_{234}}$ etc. gives us the reason for the introduction of the potentials, because it is consequently ${\displaystyle F_{\alpha \beta }={\mathrm{F}}_{\beta \alpha }}$; we write

Template:Center

where the potential vector is treated as covariant as well. We have

Template:Center

where ${\displaystyle 𝔄}$ is the vector potential, ${\displaystyle \phi }$ the scalar potential. By substitution into the first quadruple it follows

Template:Center

and here it is set

Template:Center

since the fields ${\displaystyle F_{\alpha \beta }}$ remain correct in consequence of the representation as ${\displaystyle {\mathrm{F}}_{\alpha \beta }}$, if an additional vector ${\displaystyle {\mathrm{F}}_{\alpha }}$ is added to ${\displaystyle F_{\alpha }}$; the arbitrariness in the values of the ${\displaystyle {\mathrm{\Phi }}_{\alpha }}$ is resolved by the previous condition. It follows

Template:Center

with the known solution of Template:Sc^[2]

Template:Center

where

Template:Center

is the radius vector of the reference-point ${\displaystyle y}$ with respect to point ${\displaystyle x}$. It is known, as to how the integration in the complex ${\displaystyle x^{(4)}}$ plane is carried out by means of a loop, which is clock-wise circulating around the negative imaginary semi-axis. To a fixed value system ${\displaystyle x^{(1)}x{}^{(2)}{x}^{(3)}}$ belongs a pole ${\displaystyle x^{(4)}}$, for which we have

Template:Center

Template:Pagenum upon which the loop is to be drawn together; ${\displaystyle x}$ is then a light-point for ${\displaystyle y}$, that is, ${\displaystyle R}$ is a minimal vector and ${\displaystyle x^{(4)}-y^{(4)}}$ is negative imaginary or ${\displaystyle x}$ lies on the pre-cone of ${\displaystyle y}$ (Template:Sc).

By means of the invariance of the integral forms it follows, if one uses

Template:Center

with ${\displaystyle x^{(4)}}$ as timelike coordinate, and if

Template:Center

is now defined as:

Template:Center

Template:Center

for which it follows with the aid of the potentials:

Template:Center

For the ${\displaystyle {\mathrm{\Phi }}_{\alpha }}$ the equations hold (see § 2, end):

Template:Center

or, if as before the condition Template:Pagenum

Template:Center

is imposed on them:

Template:Center

or by the introduction of the vector ${\displaystyle {\mathrm{P}}_{\alpha }}$ reciprocal to ${\displaystyle {\mathrm{P}}^{(\alpha )}}$:

Template:Center

Template:Center

Maybe it is not superfluous to mention, that for instance

Template:Center

can be transformed into the form (see § 2)

Template:Center

though this cannot be done with our previous four equations, therefore it will be avoided to denote them by ${\displaystyle ◻{\mathrm{\Phi }}_{\alpha }}$.^[3] On the other hand, the conditional equation between the ${\displaystyle {\mathrm{\Phi }}_{\alpha }}$ has the form:

Template:Center

Template:Pagenum By that, we have derived everything that is needed for the purpose of our investigation; before we proceed, however, a remark may have its place here:

The most general direction-changing transformations ${\displaystyle \frac{\partial (x)}{\partial (\overline{x})}<0}$ can namely always be traced back to a transformation ${\displaystyle \frac{\partial (x)}{\partial (\overline{x})}>0}$ multiplied by a change of direction of the coordinate axes. Now, because of the irreversibility of time (permutation of pre- and after-cone would indeed be a permutation of cause and effect), in Minkowski's ${\displaystyle S_4}$ we always have:

Template:Center

therefore we can confine ourselves to the change of direction

Template:Center

and here we see, that ${\displaystyle {ℌ}_x=F_{23}}$, ${\displaystyle {ℌ}_y=F_{31}}$, ${\displaystyle {ℌ}_z=F_{12}}$ transform as a vector of second kind, i.e.

Template:Center

while ${\displaystyle {𝔈}_x=i{F}_{14}}$, ${\displaystyle {𝔈}_y=i{F}_{24}}$, ${\displaystyle {𝔈}_z=i{F}_{34}}$ transform as a vector of first kind, i.e.

Template:Center

In the dual system

Template:Center

the transformations are exactly reversed due to the change of sign of the ${\displaystyle \sqrt{c}}$ in accordance with the rule given in § 1:

Template:Center

and

Template:Center

Template:Pagenum In Cartesian coordinates, where ${\displaystyle F_{23}^{\ast }=-i{𝔈}_x}$ etc. and ${\displaystyle F_{14}^{\ast }={ℌ}_x}$, this is of course self-evident. From this different nature of the two vectors ${\displaystyle 𝔈}$ and ${\displaystyle ℌ}$ the known advantage can be drawn, for instance, with respect to the known theorem of optics: “When standing waves are reflected, the electrical vector has a vibration node at the the mirror surface, the magnetic vector has a vibration antinode”,^[4] or with respect of the analogous theorem of the phase change by half a wave-length in the case of reflection.