Does Gravitational Time Dilation Affect Planetary Geology?

In summary, time dilation due to gravity has some interesting consequences, such as the fact that time on the surface of Mars should proceed faster than on Earth due to lower gravity. However, this difference is too small to have any significant impact on geological time scales. Scientists have also considered the implications of this for finding old Martian rocks on Earth, but the age difference is still very minimal. Lastly, while some may see this as a potential method for time travel, the actual effects on geological development are negligible.
  • #1
gonzo
277
0
I have a few questions about time dilation due to gravity. It seems to me there are some strange/interesting consequences of this that I've never seen discussed. I'm not sure what signifigance it has, but it seems like it should have some.

Basically, since gravity is lower on the surface of Mars than on the surface of Earth, then time should procede faster on Mars than on Earth (relative to each other). I know this difference is too small for a human lifetime to be significant, but it seems like it should add up to something serious on a geological time scale. Even more so for smaller planets (or non-planets) like Pluto. Doesn't this mean that they are some large number of years ahead of us in geological development in some sense? That the surface of those planets is in some sense a lot older than the surface of Earth (relative to the start of the solar system and each other)?

Like I said, I don't know if this has any meaning other than a possible science fiction story plot, but it seems interesting at least. It might have implications though if we find some old Martian rock on Earth (which has happened) and try and figure out "when" it left Mars and came to Earth. If that was long enough ago, that "when" could be radically different from an Earth and from a Mars perspective.

Also, this just let me to another thought. Time speeds up as you get closer to the center of the Earth for the same reason. Doesn't this have some sort of weird implications for geological development of the planet, where the center of the Earth is going to be quite a bit older geologically than the surface of the planet? Over several billion years this difference has to be pretty serious. Do geologists ever consider this when thinking about planetary geology theories?
 
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  • #2
There has been a science-fiction novel with a similar theme - Larry Niven's Neutron Star.

I don't know but my guess is that the time difference between Earth's surface and Mar's surface would only add up to a few minutes per billion years.


I don't think the sppeding of time inside the Earth as you move toward lower gravitation at the the center is geologically significant, but it might make a big difference inside a neutron star.
 
  • #3
gonzo said:
Time speeds up as you get closer to the center of the Earth for the same reason.

Why is this? I've never heard it, but thinking it through as you approach the center of the Earth (from the surface), a couple things happen:

1. Gravity on a per-point basis decreases, because as you approach the center of the Earth its mass distribution "above" you is roughly the same as its mass distribution "below" you.

2. Your speed relative to the speed of the surface decreases, because you're no longer on its outer rim and no longer moving at the speed of its surface.

I think these effects cancel out to some degree, making the effect (that's already very small, as pointed out by Ray Eston Smith Jr) and making it even smaller.
 
  • #4
gonzo said:
I have a few questions about time dilation due to gravity. It seems to me there are some strange/interesting consequences of this that I've never seen discussed. I'm not sure what signifigance it has, but it seems like it should have some.

Basically, since gravity is lower on the surface of Mars than on the surface of Earth, then time should procede faster on Mars than on Earth (relative to each other). I know this difference is too small for a human lifetime to be significant, but it seems like it should add up to something serious on a geological time scale. Even more so for smaller planets (or non-planets) like Pluto. Doesn't this mean that they are some large number of years ahead of us in geological development in some sense? That the surface of those planets is in some sense a lot older than the surface of Earth (relative to the start of the solar system and each other)?
Over 4+ billion years of the Earth's age, the surface of Mars would age less than 3 years more than the surface of the Earth due to gravitational time dilation, not exactly a "large number of years".
Like I said, I don't know if this has any meaning other than a possible science fiction story plot, but it seems interesting at least. It might have implications though if we find some old Martian rock on Earth (which has happened) and try and figure out "when" it left Mars and came to Earth. If that was long enough ago, that "when" could be radically different from an Earth and from a Mars perspective.
As pointed out above, the age difference would be of no significance.
Also, this just let me to another thought. Time speeds up as you get closer to the center of the Earth for the same reason.
No, it wouldn't. Gravitational time dilation is not related to the local force of the gravitational field, but rather the gravitational potential For any given body this relates to how deep you are in the gravity field> As you move towards the center of the Earth, you are moving deeper into Earth's Gravity field, and thus time will move slower, not faster.
Doesn't this have some sort of weird implications for geological development of the planet, where the center of the Earth is going to be quite a bit older geologically than the surface of the planet? Over several billion years this difference has to be pretty serious. Do geologists ever consider this when thinking about planetary geology theories?

Again, Over the age of the Earth the age difference will be quite small. We are talking about the core being less than 1 year younger than the surface, insignificant on geological time scales.
 
  • #5
some scientists think that this would be the best way for futureisitc time travel. To build a shperical hollow machine which has no gravity in the centre but has a hudge amount of gravity on the outside. Making the time on the ouside pass faster than the time on the inside.
 
  • #6
I did some number checking finally, and it does seem that on the surface of the Earth compared to no gravity it's 1 part in a billion, so that is only 1 year ever billion not very much as has been pointed out.

However, I'm confused as to why time would slow down towards the center of the Earth. Gravity starts getting less and less as soon as you go inward from the surface, where it is maximum, until it reaches zero at the center of mass, where there should be no time dilation from the Earth. What am I missing?

I plugged in some numbers for an arbitrary neutron star, and it seem you can easily get dilation ranging from 10 to 100 percent. So here's a question. Assuming you have a many billion year old neutron star, with a time dilation at the surface of 20 percent. So the surface is lagging some point in space by several hundred million years over the life time of the star.

What happens if you were to land a ship on the surface? Would you be "going back in time" several hundred million years, and thus get a radically different view of the sky when you land from when you were in orbit? Or would you only experience time change related to the amount of time it actually took you to land the ship (a few hours say)? I hope it's at least clear what I'm asking.
 
  • #7
gonzo said:
I did some number checking finally, and it does seem that on the surface of the Earth compared to no gravity it's 1 part in a billion, so that is only 1 year ever billion not very much as has been pointed out.

However, I'm confused as to why time would slow down towards the center of the Earth. Gravity starts getting less and less as soon as you go inward from the surface, where it is maximum, until it reaches zero at the center of mass, where there should be no time dilation from the Earth. What am I missing?

In the weak field case, you can think of gravitational time dilation as being caused by gravitational potential energy. You are apparently thinking of gravitational time dilation as being caused by the local acceleartion of gravity, 'g'. This is not true.

see for instance

http://hyperphysics.phy-astr.gsu.edu/hbase/relativ/gratim.html#c4

Also note, though, that g is closely related to the gravitational potential energy U=-GmM/R. Specifically, g=dU/dr.
 
  • #8
I looked at that link and am still confused. According to that formula, it still seems that time would go faster towards the center of the Earth compared with the surface. Taking the first formula (not the one using "g" on the surface) the only thing you have changing as you go towards the center are M and R, mass and radius (unless these mean somthing else here?). Mass changes faster than radius, which means that bottom of the equation approaches 1 as you approach the center of the Earth, and the two times approach each other.
 
  • #9
gonzo said:
I looked at that link and am still confused. According to that formula, it still seems that time would go faster towards the center of the Earth compared with the surface. Taking the first formula (not the one using "g" on the surface) the only thing you have changing as you go towards the center are M and R, mass and radius (unless these mean somthing else here?). Mass changes faster than radius, which means that bottom of the equation approaches 1 as you approach the center of the Earth, and the two times approach each other.

If you look at the text, T is the time at infinity and T0 is the time on the clock in the gravity well. They are related by the expression

[tex] T = \frac {T_0} {\sqrt{1-\frac {2 G M}{R c^2}}} [/tex]

Thus T > T0 always, which means the clock at infinity runs faster, and the clock in the gravity well runs slower.

There is an unfortunate typo in their series expansions, which are convenient when the time dilation is very small (as is usually the case)

[tex] T \approx T_0 (1 + \frac{GM}{R c^2}) \hspace{.5 in} T_0 \approx T(1-\frac{GM}{Rc^2}) [/tex]

Note that U = GM/R is the Newtonian potential energy per unit mass. Thus U/c^2 has the dimensions of Energy / (mass * c^2), i.e. it's dimensionless.

If you want the reading on a clock in a gravity well, the second approximation will give it as a function of the time of a clock at infinity, and as I said before, the clock in the gravity well always indicates that less time has passed than the clock at infinity.
 
  • #10
pervect said:
Note that U = GM/R is the Newtonian potential energy per unit mass.
Note: The Newtonian potential energy per unit mass is also known as the Newtonian potential.

Pete
 
  • #11
gonzo said:
Gravity starts getting less and less as soon as you go inward from the surface, where it is maximum, until it reaches zero at the center of mass, where there should be no time dilation from the Earth. What am I missing?

I think I understand why you're confused. As you head toward the center of the earth, you don't really think you're leaving its gravitational field, do you? I mean...you're sitting right in the middle of it! :smile:

The net force on your body approaches zero (as you're pulled in all directions by mass that's approximately equal on all sides), but the force is there nonetheless. In order to leave the gravitational field you'd have to move far enough away from the mass.
 
  • #12
Thank you Severian, that was exactly what I needed to here to understand why I was confused. I got it now.
 
  • #13
Janus said:
Over 4+ billion years of the Earth's age, the surface of Mars would age less than 3 years more than the surface of the Earth due to gravitational time dilation, not exactly a "large number of years".
As pointed out above, the age difference would be of no significance.
No, it wouldn't. Gravitational time dilation is not related to the local force of the gravitational field, but rather the gravitational potential For any given body this relates to how deep you are in the gravity field> As you move towards the center of the Earth, you are moving deeper into Earth's Gravity field, and thus time will move slower, not faster.


Again, Over the age of the Earth the age difference will be quite small. We are talking about the core being less than 1 year younger than the surface, insignificant on geological time scales.


Thank you Janus this is very interesting!
 
  • #14
gonzo said:
Thank you Severian, that was exactly what I needed to here to understand why I was confused. I got it now.
Sweet! Glad I could help
:smile:
 
  • #15
gonzo said:
I looked at that link and am still confused. According to that formula, it still seems that time would go faster towards the center of the Earth compared with the surface. Taking the first formula (not the one using "g" on the surface) the only thing you have changing as you go towards the center are M and R, mass and radius (unless these mean somthing else here?). Mass changes faster than radius, which means that bottom of the equation approaches 1 as you approach the center of the Earth, and the two times approach each other.
That formula is only valid for the region exterior to the earth. Inside the Earth the corresponding formula would be
[tex]t = \frac{\tau}{\sqrt{1 + \frac{2\Phi}{c^2}}}[/tex]
[tex]\Phi = \frac{1}{2}\frac{GM_{tot}r^{2}}{R^{3}} - \frac{3}{2}\frac{GM_{tot}}{R}[/tex]
where [tex]M_{tot}[/tex] is the mass of the planet, R is its radius, r is the distance of the clock inside the Earth from the center with [tex]\tau[/tex] as its time and t is the time for a far remote clock. According to this gravitational time dilation is greatest at the center.
 
  • #16
Gack! Remember once you reach the center of Earth [or mars] the gravitational potential is exactly.. zero.
 
  • #17
Chronos said:
Gack! Remember once you reach the center of Earth [or mars] the gravitational potential is exactly.. zero.

Zero GP is defined at an inifinite distance from the body for which you are measuring it and becomes increasingly negative as you approach the body in question. It is at its most negative at the center of the body.
 
  • #18
Chronos said:
Gack! Remember once you reach the center of Earth [or mars] the gravitational potential is exactly.. zero.
No. The gravitational potential for the interior is given by
[tex]\Phi = \frac{1}{2}\frac{GM_{tot}r^{2}}{R^{3}} - \frac{3}{2}\frac{GM_{tot}}{R}[/tex]
At the center this becomes
[tex]\Phi = - \frac{3}{2}\frac{GM_{tot}}{R}[/tex]
and that is where the magnitude of the potential and gravitational time dilation is at their greatest.
 
  • #19
Chronos said:
Gack! Remember once you reach the center of Earth [or mars] the gravitational potential is exactly.. zero.
Janus is correct. The potential decreases from zero outside a spherical body to -GM/R at the surface where R is the radius of the sphere. Inside the body the gravitational force is given by F = -GMr/R3 which means its still directed towards the center. For this to be true the gravitational potential must still decrease as you get to r = 0.

This can be derived using Gauss's law for gravitation, i.e.

[tex]\int \bold g_{inc} \bullet d\bold s = -4\pi G M_{inc}[/tex]

where Minc is the mass inclosed by the surface of integration and gin is the gravitational acceleration at the point on the surface of the integration. This yields

[tex]\bold g_{>} = -\frac{GM}{r^2}\bold e_r[/tex]

[tex]\bold g_{<} = -\frac{GM_{in}}{r^2} \bold e_r= -\frac{GMr}{R^3}\bold e_r[/tex]

where g> is the gravitational acceleration for r > R, g< is the gravitational acceleration for r < R and M is the total mass of the sphere. er = r/r. The corresponding gravitational potential for r > R is

[tex]\Phi(r)_{>} = -\frac{GM}{r}[/tex]

and for r < R is

[tex]\Phi(r){<} = -\frac{Mr^2}{2R^3} + C[/tex]

The gravitational potential must be a continuous function of r which means for r > R

[tex]\Phi(R)_{>} = \Phi(R)_{<}[/tex]

This means that

[tex]C = -\frac{3GM}{2R}[/tex]

So

[tex]\Phi(r)_{<} = -\frac{Mr^2}{2R^3} -\frac{3GM}{2R}[/tex]

When r = 0

[tex]\Phi(0)_{<} = -\frac{3GM}{2R}[/tex]

Pete
 
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  • #20
It's necessary to make some assumptions as to the variation of density with radius (depth) to compute the gravitational potential inside a body. Assuming that the density is constant as a function of r lead's too a "Hooke's law" force which is directly proportional to the distance, like a giant spring. This assumption leads to the results previously presented in detail by both pmb and DW.
 
  • #21
pervect said:
It's necessary to make some assumptions as to the variation of density with radius (depth) to compute the gravitational potential inside a body. Assuming that the density is constant as a function of r lead's too a "Hooke's law" force which is directly proportional to the distance, like a giant spring. This assumption leads to the results previously presented in detail by both pmb and DW.
Thanks. I forgot to say that the above derivation assumes a constant mass density.

Pete
 
  • #22
Err.. what part of the profusion of equations do not predict a zero gravitational potential at the mass center of a gravitating body? Admittedly, I use Hooke's law to arrive at the zero potential result. I fail to see how it does not apply or result in a force other than zero.
 
  • #23
Chronos said:
Err.. what part of the profusion of equations do not predict a zero gravitational potential at the mass center of a gravitating body? Admittedly, I use Hooke's law to arrive at the zero potential result. I fail to see how it does not apply or result in a force other than zero.

Let R be the radius of the earth, and g be the acceleration of gravity at the Earth's surface.

You can do work by lowering a body of mass m on a string from infinity to the surface of the earth. The total work turns out to be g*m*R = R * G*m*M/R^2. The potential is zero at infinity, and gets more negative as one approaches the surface of the earth.

You can do more work by lowering the body of mass m on a string from the surface of the Earth to the center. Since the force is g*m*r/R, the average amount of work is .5*g*m*R when you go all the way to the center.

The fact that you still have a foce shows that the potential is changing. The fact that the force is directed downward shows that the potential continues to decrease further (become more negative) as one goes to the center.

The choice of the zero point of potential at infinity is arbitrary in classical mechanics (you are allowed to add a scalar to the potential), but I don't think you have the same amount of freedom in the weak-field theory (PPN theory) of gravity. Because we assume the metric of space-time is flat at infinity, it's necessary that g_00 be 1 at infinity, which implies that the U = 0 at infinity.
 
  • #24
Janus said:
Zero GP is defined at an inifinite distance from the body for which you are measuring it and becomes increasingly negative as you approach the body in question. It is at its most negative at the center of the body.
Huh? Are you suggesting I will experience negative gravity [such as being pulled apart] at the center of mass? I seriously doubt that.
 
  • #25
Chronos said:
Huh? Are you suggesting I will experience negative gravity [such as being pulled apart] at the center of mass? I seriously doubt that.
That is not the meaning of what he said. The only measureable thing here is the gravitational force. The relationship between force F, potential energy, V, and gravitational potential [itex]\Phi[/tex] on a particle of mass m

[tex]\bold F = -\nabla V = -m\nabla \Phi[/tex]

where [itex]V = m\Phi[/itex]. Consider the radial component of this expression

[tex]F = -\frac{\partial V}{\partial r} = -m\frac{\partial \Phi}{\partial r}[/tex]

This means that only changes in the gravitational potential can be measured and that for the force to be directed towards the center of the body the potential must be a decreasing function of r. If the potential is arbitrarily given the value of zero at infinity and must decrease with decreasing r then it follows that the gravitational potential must be negative. The gravitational force at the center of the body is zero no matter what value you let the gravitational potential be at the center.

Pete
 
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  • #26
pmb_phy said:
...[tex]\int \bold g_{inc} \bullet d\bold s = -4\pi G M_{inc}[/tex]...
...[tex]\Phi(r){<} = -\frac{Mr^2}{2R^3} + C[/tex]...
...[tex]\Phi(r)_{<} = -\frac{Mr^2}{2R^3} -\frac{3GM}{2R}[/tex]...
Corrections:
[tex]\int \bold g_{inc} \bullet d\bold a = -4\pi G M_{inc}[/tex]
[tex]\Phi(r)_{<} = -\frac{GMr^2}{2R^3} + C[/tex]
[tex]\Phi(r)_{<} = -\frac{GMr^2}{2R^3} -\frac{3GM}{2R}[/tex]
 
  • #27
Chronos said:
Gack! Remember once you reach the center of Earth [or mars] the gravitational potential is exactly.. zero.
That's gravitational potential energy you are talking about. Not the field strength (as I understand it "gravitational potential" is the field strength).
 
  • #28
russ_watters said:
That's gravitational potential energy you are talking about. Not the field strength (as I understand it "gravitational potential" is the field strength).
Neither the gravitational potential, nor the gravitational potential energy which is proportional to that are zero at the center when as in this case the zero point is taken to be at infinity.
 
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  • #29
russ_watters said:
That's gravitational potential energy you are talking about. Not the field strength (as I understand it "gravitational potential" is the field strength).

The quantity [tex]\Phi[/tex] is referred to in my text as just "The Newtonian Potential". See MTW, "Gravitation", pg 445,1073 and elsewhere. It's equal to the Newtonian gravitational potential energy per unit mass. It has the additional requirement that it is zero at infinity, so it doesn't have the same degree of freedom to add a scalar quantity to it that potential energy does in classical mechanics. Hence the confusion about the value of the potential in the center of a mass. Classically, you could set the potential energy at the center of the mass to zero, and to a positive value at infinity. But here we require the potential at infinity to be zero.

It's useful in general relativity in the weak field limit, in spite of its name.

In the literature of PPN formalism, [tex]-\Phi[/tex] is traditionally called U (MTW, pg 1073), though it's called by the more-difficult-to-type [tex]\Phi[/tex] elsewhere in the book.
 
  • #30
Hi to All,

I want to know the gravitational time dilation on Jupiter. I saw the equation for it but I'm not sure what the value of "to" is. I'm looking for "t" on the surface is "to" the time at the center of jupiter? If I set "to" to 1, "t" is bigger, indicating a gain of time rather than a loss.

Thanks for your help,
 
  • #31
Chronos said:
Gack! Remember once you reach the center of Earth [or mars] the gravitational potential is exactly.. zero.

I didn't intend to reply to this old thread. Please delete this post.
 
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1. How does gravitational time dilation affect planetary geology?

Gravitational time dilation is the phenomenon where time passes at different rates depending on the strength of gravity. This means that on planets with stronger gravitational fields, time will pass slower compared to planets with weaker gravitational fields. This can have an impact on the geological processes on a planet, as they may occur at different rates due to the difference in time passing.

2. Can gravitational time dilation change the age of a planet?

No, gravitational time dilation does not change the actual age of a planet. It only affects the perception of time passing. The age of a planet is determined by its formation and does not change due to gravitational time dilation.

3. Is gravitational time dilation the same on all planets?

No, gravitational time dilation is not the same on all planets. It depends on the strength of the planet's gravitational field, which is determined by its mass and size. Therefore, planets with different masses and sizes will have different levels of gravitational time dilation.

4. How does gravitational time dilation affect the formation of geological features?

Gravitational time dilation can affect the formation of geological features by altering the rate at which geological processes occur. For example, on a planet with a stronger gravitational field, erosion and weathering may occur at a slower rate compared to a planet with a weaker gravitational field. This can result in different geological features being formed over time.

5. Can gravitational time dilation affect the length of a day on a planet?

Yes, gravitational time dilation can affect the length of a day on a planet. As time passes at different rates on planets with different gravitational fields, it can impact the rotation of the planet. This means that the length of a day on a planet with a stronger gravitational field may be longer compared to a planet with a weaker gravitational field.

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