Everything you're saying holds up, except for this one thing:

> a beam that cannot flex and is incredibly long

In physics, we often times talk about "rigid bodies" and make the assumptions that they are infinitely stiff, but that's just a "small thing, moving slow" assumption- where they appear to be completely rigid. In real life, materials are not completely rigid.

Now, you might think "that's just an engineering problem, we can just design something to be really stiff. But you can't. Information- including compressions and rotations, travel through a material at that material's speed of sound. Which makes sense if you think about it, sound waves are compressions passing through a material.

So, if you had a really long rod, and you started rotating it faster and faster, the rod would start to bend and then shear. And that's not an engineering problem- it's a real physics one.

I was actually asking myself this: If the rod did not bend at all - could we even move it? I mean without any pressure wave travelling through the material it could not accelerate. So wouldn't perfect rigidity require an infinite speed of sound inside the material? That would make it impossible, even in a "ideal" calculation...

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Rigidity and relativity is more complicated than you might think.

Firstly, relativity constrains the speed of sound in an object. This means for example you cannot have a rigid pole where pushing one end causes the other end to move instantaneously.

Secondly, relativity constrains rigidity even further. We could conspire to apply forces across an object at the same time in its instantaneous rest frame such that the object never experiences deformation in its rest frame. When we do this the object is called "Born rigid" (after Max Born). However it turns out it is impossible to for an object to be Born rigid under all types of motion. The motion in your son's hypothetical experiment would be an example of a type of motion where it is impossible to even maintain Born rigidity.

Even if we assume a non flexing support rod, you'd need to apply torque to the axle to move the object. The energy required to move the object wouldn't change, so you'd be looking at infinite torque necessary to turn the axle.

In principle, yes. Infinite rigidity would mean infinite speed of sound. As soon as the velocity of any part of the rod approaches the speed of light, the torque necessry to further accelerate the rod would go towards infinity. However, as others have pointed out, infinite rigidity violates relativity as the speed of sound itself cannot exceed the speed of light.

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In classical mechanics, if the stiffness (ie the relevant elastic moduli for the wave type) tends to infinity or the density tends to zero then the speed of sound tends to infinity. Am I correct to think that when you apply special relativity, the speed of sound would tend to c and not infinity in those limits?

Nice explanation. If an object (like a very long steel rod) could be infinitely rigid, you could communicate information faster than the speed of light, which is obviously not gonna happen.

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