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I've recently started learning Physics using University Physics (Fourteenth Edition) and I've come to the subject of (sound) shock waves.

It's explained in the case of an aircraft travelling at supersonic speed with an image that is similar to this:

enter image description here

Now from what I've understood, each circle represents the crest of a longitudal wave. Now I understand that anyone standing in the 'cone' will simply receive the circle crests and undergo the Doppler effect. But what I don't understand is how the two lines (or the cone if you want to go 3-dimensional) are a wave. It is explained as there being constructive interference of the blue waves there, but I don't see any point on the shock wave lines where the circle crests overlap? What kind of wave is this shock wave, longitudal? Does it propagate, in which direction? I am failing to understand what a shock wave 'looks like.'

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  • $\begingroup$ Have a look at this. youtube.com/watch?v=gWGLAAYdbbc $\endgroup$ – Farcher Jan 18 '17 at 16:09
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    $\begingroup$ Probably related: physics.stackexchange.com/q/131812 $\endgroup$ – Kyle Kanos Jan 18 '17 at 17:49
  • $\begingroup$ Yeah that video is fun but doesn't really answer my question, and that other question is interesting but asks more for a definition and I am more interested in where the crests of this shockwave are, or whether it's one giant crest or anything visual that connects to the picture in my OP. $\endgroup$ – QuestionMaker Jan 18 '17 at 19:45
  • $\begingroup$ @QuestionMaker, you can see "shock waves" in 2 dimensions on water. For a "zero velocity" boat in a lake, rocking the boat produces circular wave patterns, as expected. When the motor is engaged, the boat speeds up and chases the waves that it makes. At some point, the boat "planes out", and forms the familiar "V" pattern in the water. At that point, the boat is moving faster than the waves it produces, and all the wave crests "stack up" to form that "V" pattern. $\endgroup$ – David White Jul 23 '18 at 18:34
  • $\begingroup$ @David White. The Kelvin bow wave of a boat on deep water always makes an angle of 19.5 degrees independently of how fast the boat moves. This because water waves are dispersive and do not have a set velocity. Thus a bow wave is a bad example of a shock wave. $\endgroup$ – mike stone Aug 23 '19 at 16:05
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It is explained as there being constructive interference of the blue waves there, but I don't see any point on the shock wave lines where the circle crests overlap?

I put a nice picture of a condensation cone in the following answer https://physics.stackexchange.com/a/281767/59023 (and below) that may help illustrate what that cone represents. The cone is the leading edge of a shock wave and it is not oscillatory like the more standard sine wave one may be used to.

F-18 breaking sound barrier

I threw togther a nice little animation of nonlinear wave steepening at https://physics.stackexchange.com/a/139436/59023 (and below). You can see that the gradient scale length of the leading edge of the soliton slowly decreases (i.e., it becomes more like a sharp ledge than a smooth sloping hill). If the steepening continues to the gradient catastrophe and does not stop, the wave will break (e.g., like water waves in high winds or near shore). If the steepening is balanced by some form of energy dissipation, a stable discontinuity can form, not a periodic wave. This is a shock wave.

nonlinearly steepening magnetosonic wave example

The condensation cone only arises during the initial forming of the shock wave, when the pressure immediately behind the leading edge of the steepening sound wave drops due to rarefaction. Once the shock forms and is stable, the density, pressure, and temperature downstream (i.e., behind the shock) are higher and remain high. Obviously, these parameters slowly equilibriate with the surrounding medium far enough away from the shock, but in the immediate vicinity, the shock resembles a step function.

The circles in that image are really just meant to be a visualization tool. In some contexts, one may use circles to illustrate sound waves (or other types of waves) being emitted by a moving source (e.g., some Doppler effect illustrations use this).

What kind of wave is this shock wave, longitudal?

Yes, a shock wave is a longitudinal wave, specifically a nonlinearly steepened sound wave that has reached a balance between steepening and energy dissipation. The resulting phenomena has one "crest," to use your term, and no oscillations. It is a discontinuous transition between the upstream(unshocked) and downstream(shocked) regions.

Does it propagate, in which direction?

Yes, shock waves propagate. In your picture example, the shock would propagate parallel to arrows (i.e., orthogonal to the cone). A sonic boom associated with shock waves in Earth's atmosphere is the pressure pulse of the shock itself.

I am failing to understand what a shock wave 'looks like.'

Look at the link I shared above for the condesation cone or go to Google and type in "shock wave" then click on images. There have been thousands of images produced that visualize the density/pressure perturbation that is a shock wave.

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  • $\begingroup$ All right so if the picture I posted was animated over time, I'd see the circles growing, and therefore the shockwave line moves to the right/bottom, which is its propagation. And over the entire blue shockwave line there is an intensely high air pressure? Am I correct in this understanding? $\endgroup$ – QuestionMaker Jan 19 '17 at 22:22
  • $\begingroup$ @QuestionMaker - Well, the strength of the shock wave does decrease away from the source (i.e., piston) but in the vicinity of the source the blue cone would represent the shock ramp which is a boundary between atmospheric and shocked/compressed, high pressure air. $\endgroup$ – honeste_vivere Jan 19 '17 at 22:54
  • $\begingroup$ But is the air highly compressed near that blue line? How does that work if I take a look at the picture I posted? The air is compressed around the blue cirles because they are sound waves, but how do these pressure amplitudes 'add up'? $\endgroup$ – QuestionMaker Jan 19 '17 at 23:14
  • $\begingroup$ @QuestionMaker - Yes, the air is highly compressed near the blue line. You can see this in the picture I posted by the change in the index of refraction just in front of the condensation cones, which results from a change in local air properties. Here that would be an abrupt increase in pressure, temperature, and density at the shock wave ramp (i.e., the step in the step function). $\endgroup$ – honeste_vivere Jan 20 '17 at 14:05
  • $\begingroup$ But how do the pressures of the circles build up if they only overlap on a few points? $\endgroup$ – QuestionMaker Jan 20 '17 at 21:25

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