Planet made entirely of liquid

In summary, the conversation discusses the pressure in a hypothetical planet with a radius R, uniform density, and no rotation. The formula for pressure in a liquid is given, but there are discrepancies when applying it to this situation due to the changing gravitational force as you move closer to the center of the planet. After some discussion and revisions, it is determined that the pressure at the center would be zero and the density of the liquid would depend on the temperature at the core. The conversation also touches on the possibility of a planet made entirely of water and the challenges in determining its internal temperature and phases.
  • #1
ApeXaviour
35
0
Okay obviously a hypothetical situation, this planet has a radius [tex]R[/tex], uniform density, and it doesn't rotate.

Pressure in a liquid is given by
[tex]p=\rho g d[/tex] where [tex]d[/tex] is the depth.

So the liquid pressure a distance [tex]r[/tex] from the centre of the planet is.
[tex]p=\rho g (R-r)[/tex] (where r<R)
But [tex]g[/tex] is also a function of [tex]r[/tex]. A little bit of fiddling with Newton's gravitation law gives:
[tex]g(r)=GM\frac{r}{R^3}[/tex]
So...
[tex]p=\rho GM\frac{r}{R^3}(R-r)[/tex]

This would mean, at [tex]r=0[/tex] the core of the planet is under zero pressure...! Em, I don't believe this to be correct, so what am I missing? am I slipping up somewhere? Am I putting too much stock in the formula: [tex]p=\rho g d[/tex]?
 
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  • #2
your first equation is actually the result of a more general equation after some integration, it refers specifically to a column of liquid in which g remains constant. You need to go right back to the roots.

The reason you found pressure to be zero is because g is zero at the centre.
 
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  • #3
Hmm.. not sure why this was moved, it's not homework, I've actually just graduated. It's something I was debating with a friend.

Okay I see how it doesn't work as it assumes g is constant.

Okay back to basics, let me try again.
Pressure is force over area, in this case "weight" over area.

Taking a column of water between r and R, of height h and base area A. Taking an infinitesimal segment of the liquid at the top, it's weight is given by:
[tex]dF=\rho .A .g(r). dh[/tex]
where [tex]g(r)=GM\frac{r}{R^3}[/tex] and [tex]h = R-r[/tex]
so [tex]dh=-dr[/tex]
so now the total force/weight is [tex]F=\rho A GM \int_{R}^{r} -g(r) dr[/tex]

So now pressure is:
[tex]p=\frac{F}{A}=\rho GM \frac{1}{2}(\frac{1}{R}-\frac{r^2}{R^3})[/tex]

How does that look? I'm happier with it, as it appears to be max when r is zero and min when r is max.
 
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  • #4
It looks wrong to me, p should equal zero for r=R.
 
  • #5
Good point, that didn't occur to me. But look at it again, it actually does equal zero when r=R. The bracketed part goes to (1/R - 1/R).

Hmm I'm pretty confident in it now. What do people think?
 
  • #6
Why did you take a column of water? Especially if you're near the center, I assume you'd need to look at a sphere, as the force wouldn't all be pointing in the same direction as you move to points near where you're calculating
 
  • #7
I don't quite see what you're getting at. It's static so the only force is gravitational, which is radial. Imagine the column as being very thin and pointing in a radial direction.
 
  • #8
Oh yes so it is! silly me. Note that because M=rho*V you should be able to find a more elegant form of this equation.
 
  • #9
Office_Shredder said:
Why did you take a column of water? Especially if you're near the center, I assume you'd need to look at a sphere, as the force wouldn't all be pointing in the same direction as you move to points near where you're calculating

It looks like he took infinitesimal concentric spheres of liquid and totaled up the force from each of these thin shells, which looks to me like it should work since the force is uniform and always pointing toward the center. Interesting problem!
 
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  • #10
So how much?

Sooo . . . assuming an Earth mass world, how high is the pressure at the center? What is the density of the water there? Would it still be water or some sort of metal-like substance or what?
 
  • #11
Agua88 said:
Sooo . . . assuming an Earth mass world, how high is the pressure at the center? What is the density of the water there? Would it still be water or some sort of metal-like substance or what?

That would also depend on the temperature. We could put it in by hand, which would mean we could choose what phase we wanted. Or we could try coming up with a full model of the planet, but then we'd be constrained by reality.
 
  • #12
Temperature

Well with NASA about to publish a list of world types that might support life, and one of the types being a model made purely of water, I would think we would want to arrange it so that the surface temperature, under an earthlike atmosphere, would be around 80 degrees Fahrenheit or thereabouts. No idea what temperature that would make the interior.

We'd want to assume a standard rotation, not too different from that of Earth, to avoid weird freezing problems on the backside and such.
 

What is a "Planet made entirely of liquid"?

A planet made entirely of liquid is a hypothetical celestial body that is composed primarily of a liquid substance, such as water or lava, rather than solid materials like rock and metal.

Can a planet made entirely of liquid exist in our solar system?

There are currently no known planets in our solar system that are made entirely of liquid. However, there are several moons in our solar system, such as Jupiter's moon Europa, that are believed to have liquid oceans beneath their icy surfaces.

How would a planet made entirely of liquid form?

It is believed that a planet made entirely of liquid would form in a similar way to other planets, through the process of accretion. However, the composition of the planet's materials and the conditions of its environment would be different, resulting in a planet that is predominantly liquid instead of solid.

Could life exist on a planet made entirely of liquid?

It is possible that life could exist on a planet made entirely of liquid, as long as the liquid is able to support the basic building blocks of life, such as carbon, water, and energy. However, the conditions on such a planet would likely be very different from Earth and would require unique adaptations for life to thrive.

How would we study a planet made entirely of liquid?

Studying a planet made entirely of liquid would be a significant challenge, as traditional methods of observation and exploration, such as sending probes or rovers, would not be feasible due to the liquid surface. Scientists would need to develop new technologies and techniques, such as remote sensing tools, to study such a planet from a distance.

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