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I had a asked a question about six months back what direction forces due to pressure must be pointing and I got a pretty good answer for it (here). Thinking a bit more deeply about the answer, I started getting confused how the pressure always wants to contract a body rather than expand it?

THe following equation is written in the mentioned answer:

$${\bf F}_{net}=-\int_S p{\bf n} dS$$

If I recall correctly, we consider the normal vector as pointing outside from the surface we are integrating, hence for a small area element , we are saying the pressure would push it inwards. But why/ how must pressure push inwards rather than outwards?

More simply put, why does pressure push rather than pull?

Note : I do understand we can simply say that the most direct answer is that "It is simply what we observe in real life" but why exactly is it this which we observe in real life?

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  • $\begingroup$ Because if you start with an infinite solid and cut it in half, it takes energy to break all the bonds. You are left with a bunch of atoms on the surface that are unhappy since their bonds are not fully satisfied (and to make them unsatisfied in the first place took energy). $\endgroup$
    – Jon Custer
    Commented Nov 13, 2020 at 15:41
  • $\begingroup$ How does the infinite solid concept be applied to explain why fluids want to contract materials inside? $\endgroup$
    – Brian
    Commented Nov 13, 2020 at 15:43
  • $\begingroup$ Because for the thought process you start with a situation where there is no surface at all, and then introduce one to see what the surface brings to the situation. Since it takes energy to form the surface, it is clear that objects with surfaces will want to minimize their surface area to minimize that area. $\endgroup$
    – Jon Custer
    Commented Nov 13, 2020 at 15:44
  • $\begingroup$ Wow ... I don't think I can say confidently that I fully understand what you said yet but I don't think I would have ever thought it in that way $\endgroup$
    – Brian
    Commented Nov 13, 2020 at 15:45
  • $\begingroup$ " surfaces will want to minimize their surface area to minimize that area. –" .. did you mean "Minimize the energy" $\endgroup$
    – Brian
    Commented Nov 14, 2020 at 5:55

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It's easy to imagine a situation in which a billion billion billion molecules are bouncing off a surface essentially simultaneously. This happens any time we place a solid in a fluid, for example. Each strike would deliver a "kick" of momentum if the solid surface were allowed to move inward, and in fact this is precisely how pressure is defined: that intensive variable that tends to transfer energy by shrinking a volume. (Put another way, one of the energy term in the fundamental thermodynamic relation is $-P\,dV$, where the pressure $P$ is the conjugate variable to the volume $V$.)

It's harder to imagine a situation in which a billion billion billion molecules adhere to and tug on a surface. In this situation, however, you would see an equitrixial normal tensile stress, i.e., a "negative pressure" or tendency for the object to expand.

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