Mathematical Principles of Theoretical Physics

2.2. LORENTZ INVARIANCE 55

or equivalently,

H 1 =

∂A 3

∂x^2

−

∂A 2

∂x^3

, H 2 =

∂A 1

∂x^3

−

∂A 3

∂x^1

, H 3 =

∂A 2

∂x^1

−

∂A 1

∂x^2

,

E 1 =

∂A 0

∂x^1

−

∂A 1

∂x^0

, E 2 =

∂A 0

∂x^2

−

∂A 2

∂x^0

, E 3 =

∂A 0

∂x^3

−

∂A 3

∂x^0

,

the first pair of the Maxwell equations (2.2.33) and (2.2.34) are in the form:

(2.2.39)

∂Gμ ν

∂xν

= 0 forμ= 0 , 1 , 2 , 3.

The second pair of the Maxwell equations (2.2.35) and (2.2.36) are

(2.2.40)

∂Fμ ν

∂xν

=

4 π

c

Jμ forμ= 0 , 1 , 2 , 3.

It is clear that the Maxwell equations (2.2.39) and (2.2.40) are covariant under the Lorentz
transformations. In fact, (2.2.39) and (2.2.40) can be equivalently written as

∂νGμ ν= 0 , ∂νFμ ν=

4 π

c

Jμ.

Also, two electromagnetic dynamic equations and the chargeconservation law are written
as

(2.2.41)

∂ ρ

∂t

+divJ= 0.

The motion equation in an electromagnetic field is given by

(2.2.42) m

dv

dt

=eE+

e

c

v×H.

It is clear that (2.2.41) can be written as

(2.2.43) ∂μJμ= 0 ,

which is Lorentz invariant.
The Lorentz covariance of the motion equation in an electromagnetic field follows from
the following Lorentz covariant formulation of (2.2.42):

(2.2.44) m

duμ

ds

=

e

c^2

Fμ νuν forμ= 0 , 1 , 2 , 3 ,

whereuμis the 4-D velocity given by (2.2.26), andFμ νis as in (2.2.38).
In summary, all electromagnetic equations can be written inthe Lorentz covariant forms
given by (2.2.39)-(2.2.40), (2.2.43) and (2.2.44), and the Lorentz invariance of these equa-
tions follows.