Transform Maxwell Equations into k-space

spookyfw

Dear fellow physicists,

looking at the derivation for the maxwell equations into k-space, I've stumbled upon something that seems not so logical to me. It is concerning the two parts where they transform [itex]\nabla \times E [/itex] and [itex]\nabla \bullet E [/itex] on page 27 (on the sheets 14).
http://www.scribd.com/doc/15466480/E...rcises#page=27

After integrating by parts they just state that the first term goes to zero. But for negative infinity it appears more to me that this term is actually blowing up. Is there something that I am missing and someone could me to?

Thank you very much in advance,
spookyfw

torquil

The term is zero because they have assumed that E(t,x) -> 0 as x -> +/- infinity.

vanhees71

I don't find the exercise in this manuscript you link, but it's pretty simple. Just write all the fields in terms of their Fourier transform. Using the HEP-communities convention this reads, e.g., for the electric field
[tex]\vec{E}(t,\vec{x})=\int_{\mathbb{R}^4} \frac{\mathrm{d}^4 k}{(2 \pi)^4} \hat{\vec{E}}(k) \exp(-\mathrm{i} k \cdot x).[/tex]
I use the west-coast convention, i.e.,
[tex]k_{\mu} x^{\mu}=:k \cdot x=(k^0 x^0)-(\vec{k} \cdot \vec{x}).[/tex]
Now consider Gauss's Law as an example. In time-position representation it reads
[tex]\vec{\nabla} \cdot \vec{E}=\rho[/tex]
(Heaviside-Lorentz units). Applying the differential operator on the Fourier transform gives
[tex]\int_{\mathbb{R}^4} \frac{\mathrm{d}^4 k}{(2 \pi)^4} \mathrm{i} \vec{k} \cdot \hat{\vec{E}}(k) \exp(-\mathrm{i} k \cdot x)=\rho(t,\vec{x})=\int_{\mathbb{R}^4} \frac{\mathrm{d}^4 k}{(2 \pi)^4} \hat{\rho}(k) \exp(-\mathrm{i} k \cdot x).[/tex]
Since the Fourier transformation is invertible this means that
[tex]\mathrm{i} \vec{k} \cdot \hat{\vec{E}}(k)=\hat{\rho}(k).[/tex]
In the same way you get all the other Maxwell equations in wave-number representation.

spookyfw

ah. that makes perfect sense. Thank you very much :).

PhilDSP

It can also be very helpful to keep in mind Euler's identities which make it possible to visualize the waveform in exponential form:

[itex]e^{jx} = cos \ x + j \ sin \ x[/itex]
[itex]e^{-jx} = cos \ x - j \ sin \ x[/itex]

[itex]cos \ x = \frac{e^{jx} + e^{-jx}}{2}[/itex]
[itex]sin \ x = \frac{e^{jx} - e^{-jx}}{2j}[/itex]

Similar Threads for: Transform Maxwell Equations into k-space
Thread	Forum	Replies
independent equations of maxwell equations	Classical Physics	23
Galilean transform and the maxwell equations	Special & General Relativity	7
Einstein holding Maxwell's equations above Newton's equations	Special & General Relativity	26
Maxwell's equations VS. Lorentz & Coulomb force equations	Classical Physics	65
Why Maxwell's equations cannot be assumed in empty space	General Physics	1

torquil	The term is zero because they have assumed that E(t,x) -> 0 as x -> +/- infinity.

spookyfw	Transform Maxwell Equations into k-space ah. that makes perfect sense. Thank you very much :).

PhilDSP	It can also be very helpful to keep in mind Euler's identities which make it possible to visualize the waveform in exponential form: [itex]e^{jx} = cos \ x + j \ sin \ x[/itex] [itex]e^{-jx} = cos \ x - j \ sin \ x[/itex] [itex]cos \ x = \frac{e^{jx} + e^{-jx}}{2}[/itex] [itex]sin \ x = \frac{e^{jx} - e^{-jx}}{2j}[/itex]