How to make sense of the Green's function of the 4D wave equation?

For ease of reference in this post equations are numbered as in ref. 1.

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The expression given is surprisingly useless for actual calculations. But it seems to be the best we can do with the usual functional notation to express the actual, quite well-defined, distribution. Below I'll try to make it more understandable.

Let's start from the way $(36)$ was derived. The authors in ref. 1 derived it by integrating the Green's function for (5+1)-dimensional wave equation,

$$G_5=\frac1{8\pi^2c^2}\left(\frac{\delta(\tau)}{r^3}+\frac{\delta'(\tau)}{cr^2}\right),\tag{32}$$

where $\tau=t-r/c$, along the line of uniformly distributed sources in 5-dimensional space, using the integral

$$G_{n-1}(r,t)=2\int_r^\infty s(s^2-r^2)^{-1/2}G_n(s,t)ds,\tag{25}$$

where $r=r_{n-1}$ is the radial coordinate in $(n-1)$-dimensional space.

Remember that a Green's function for a wave equation is the impulse response of the equation, i.e. the wave that appears after the action of the unit impulse of infinitesimal size and duration, $f(r,t)=\delta(r)\delta(t)$. Let's replace this impulse with one that is finite at least in one variable, e.g. time. This means that our force function will now be $f(r,t)=\delta(r)F(t)$, where $F$ can be defined as

$$F(t)=\frac{(\eta(t+w)-\eta(t))(w+t)+(\eta(t)-\eta(t-w))(w-t)}{w^2},$$

which is a triangular bump of unit area, with width (duration) $2w$. The choice of triangular shape, rather than a rectangular one, is to make sure we don't get Dirac deltas when differentiating it once.

Then, following equation $(34)$, we'll have the displacement response of the (5+1)-dimensional equation, given by

$$\phi_5(r,t)=\frac1{8\pi^2c^2}\left(\frac{F(\tau)}{r^3}+\frac{F'(\tau)}{cr^2}\right).\tag{34}$$

Now, to find the displacement response $\phi_4(r,t)$ of the (4+1)-dimensional equation, we can use $\phi_5$ instead of $G_5$ in $(25)$. We'll get

$$\phi_4(r,t)= \frac1{4c^3\pi^2r^2w^2} \begin{cases} \sqrt{c^2(t+w)^2-r^2} & \text{if }\,ct\le r<c(t+w),\\ \sqrt{c^2(t+w)^2-r^2}-2\sqrt{c^2t^2-r^2} & \text{if }\,c(t-w)<r<ct,\\ \sqrt{c^2(t+w)^2-r^2}-2\sqrt{c^2t^2-r^2}+\sqrt{c^2(t-w)^2-r^2} & \text{if }\,r\le c(t-w),\\ 0 & \text{otherwise.} \end{cases}$$

Here's a sample of $\phi_4(r,t)$ for $c=1,$ $t=10,$ $w=0.011:$

What happens in the limit of $w\to0$? By cases in the above expression:

1. The first case (blue line in the figure above) corresponds to the leading edge of the force function bump, it's located outside of the light cone of the Green's function $G_4$. As $w\to0$, the area under its curve grows unboundedly, tending to $+\infty$.
2. The second case (orange) corresponds to the trailing edge of the bump. A zero inside the domain of this case splits the function into a positive and negative parts. The integral of this function times $r^3$ diverges to $-\infty$.
3. The third case (green) corresponds to the wake after the force function bump ends. It's negative in the whole its domain, and the integral of it times $r^3$ diverges to $-\infty$. The term itself in the limit of $w\to0$ becomes, for $r<ct$, exactly the second term of $(36)$.

Together, however, the integral $\int_0^\infty r^3\phi_4(r,t)\,\mathrm{d}r$ for $t>w$ remains finite, equal to $\frac t{2\pi^2},$ regardless of the value of $w.$

Conclusions:

• The Green's function does exist and is a well-defined distribution
• The equation $(36)$ formally does make sense
• We can do calculations using $\phi_4$ instead of the $G_4$ from $(36)$, taking the limit $w\to0$ at appropriate times.

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References:

1: H. Soodak, M. S. Tiersten, Wakes and waves in N dimensions, Am. J. Phys. 61, 395 (1993)