If the support of a quantum mechanical position wave function is a bounded interval, and that interval is expanding or contracting, then I think it cannot change in any direction faster than $c$. To clarify, Consider the following example:
If a one dimensional position wave function (which is not acted upon by any internal or external potential) is measured at $t_0$ and the result is position eigenstate $x = 0$ and then, at $t_0 + \Delta t$, we perform a momentum measurement, resulting in a momentum eigenstate $p_{t_0 + \Delta t}$, then at $t \ge (t_0 + \Delta t)$, the position wave function is a plane wave and the length of the interval of its support cannot excede $(|p_{t_0 + \Delta t}|( (t - (t_0+ \Delta t)) + c \Delta t)$, which cannot excede $c( t - t_0)$.
My question is, if the above is true (which I would think it is), then if the support of a position wave function is a bounded interval, does the Klein-Gordon equation, or Dirac equation, limit the speed of the expansion or contraction of that interval, in any direction, to being no faster than $c$?
