Calculate Time Difference: Relativity Equation for Sun and Earth Masses

  • Thread starter Thread starter kajak
  • Start date Start date
  • Tags Tags
    Relativity
kajak
Messages
2
Reaction score
0
Hey everyone,

This is my 1st post here. I need help in finding an equation. I read the time moves slower for larger objects that smaller ones. For example a day form the sun’s point of view could be equal to let's say a month in earth’s view. So if I have the mass of Earth and the sun’s mass how can I calculate the exact difference in time? I.e.: 1 sun day equals how many human days. I hope o asked in a clear way. I’m not asking how many times the Earth rotates in 1 sun rotation. Thanks in advance
 
Physics news on Phys.org
Time moves more slowly in a gravitational field, but the difference between the Sun and Earth gravitational fields is not that great. Gravity depends on density and distance from the centre of gravity so the sun although far larger than the Earth does not experience a time frame that is greatly different to that on Earth.
 
well i am aware of that. i gave the Earth and the sun as examples. i need the equation to calculate larger sizes.
 
It has nothing to do with size - clocks run slower in a stronger gravitational potential - if you placed a clock "A" close to an object the size of the Earth that had a much larger density than the earth, the clock "A" would run slower than a clock "B" placed near the surface of the Sun.
 
Last edited:
In order to understand this you have to examine the behaviour of gravity which is inversely proportional to the distance from the centre of gravity. In other words a clock at sea level and a clock at the top of a tall building will measure time at different rates, even though they are both on Earth. Even your feet experience more gravity than does your head.

Try this example which I hope will help you to understand how a gravity field operates. The mass of the Earth is 81.3 times greater than the Moon, so we might expect the Earth’s gravity to be 81.3 times greater than that of the moon. Gravity weakens as we move away from the centre of gravity. This means that on the surface of the moon, we are 1,738 km from its centre of gravity but on the Earth’s surface, we are 6,371 km from the centre of gravity. This distance is 3.666 times greater on Earth, so to compare surface gravity we need to divide Earth’s 81.3 times greater gravitational potential by 3.666(squared) or 13.44. The result is that Earth’s gravity is only 6.05 times greater than the moon’s despite its mass being 81.3 times greater.
 

Thread 'I don't see how a black hole's event horizon can be crossed'

OK, so this has bugged me for a while about the equivalence principle and the black hole information paradox. If black holes "evaporate" via Hawking radiation, then they cannot exist forever. So, from my external perspective, watching the person fall in, they slow down, freeze, and redshift to "nothing," but never cross the event horizon. Does the equivalence principle say my perspective is valid? If it does, is it possible that that person really never crossed the event horizon? The...
View full post »

Thread 'Synchronizing clocks in an inertial frame if light is anisotropic'

ASSUMPTIONS 1. Two identical clocks A and B in the same inertial frame are stationary relative to each other a fixed distance L apart. Time passes at the same rate for both. 2. Both clocks are able to send/receive light signals and to write/read the send/receive times into signals. 3. The speed of light is anisotropic. METHOD 1. At time t[A1] and time t[B1], clock A sends a light signal to clock B. The clock B time is unknown to A. 2. Clock B receives the signal from A at time t[B2] and...
View full post »

Thread 'Is the variation of the metric ##\delta g_{\mu\nu}## a tensor?'

From $$0 = \delta(g^{\alpha\mu}g_{\mu\nu}) = g^{\alpha\mu} \delta g_{\mu\nu} + g_{\mu\nu} \delta g^{\alpha\mu}$$ we have $$g^{\alpha\mu} \delta g_{\mu\nu} = -g_{\mu\nu} \delta g^{\alpha\mu} \,\, . $$ Multiply both sides by ##g_{\alpha\beta}## to get $$\delta g_{\beta\nu} = -g_{\alpha\beta} g_{\mu\nu} \delta g^{\alpha\mu} \qquad(*)$$ (This is Dirac's eq. (26.9) in "GTR".) On the other hand, the variation ##\delta g^{\alpha\mu} = \bar{g}^{\alpha\mu} - g^{\alpha\mu}## should be a tensor...
View full post »

Similar threads

I The Derivative Nature of Time and Its Relation to Earth's Rotation and Speed
Replies
38
Views
5K
B How quickly does the Earth feel the effects of a halved Sun's mass?
Replies
38
Views
3K
B Earth time dilation vs Sun time dilation
Replies
3
Views
3K
I Confused about time dilation -- motion vs energy
Replies
9
Views
364
I Sun Disappearance: Impact on Earth's Path
Replies
20
Views
4K
I Difference between the Shapiro Delay and time dilation?
Replies
1
Views
1K
I SR-time dilation vs GR-time dilation on rotating Earth
2
Replies
79
Views
5K
I Speed Difference of Time on Poles vs Equator of Earth and Other Planets
Replies
16
Views
4K
I Questions about a thought experiment involving time dilation
Replies
2
Views
1K
B Calculating Time taken to reach speed with Time Dilation
Replies
18
Views
1K

Hot Threads

Recent Insights

Back
Top