physicsdude30 said:I am trying to learn more about General Relativiity. We had Newton's Law of Gravitation. When does it not work? I heard at very high speeds, high mass bodies, and when the distance to a high mass body is very short (Mercury for example, I think)? How does Newton's Gravitation differ mathematically in these scenarios?
Matterwave said:Also, the bending of light near a star is purely from GR. Newtonian physics would have light not bend at all near a star since light is mass-less.
Matterwave said:Even if you attribute a "pseudo mass" (using E=mc^2) to photons, Newton's predictions of the bending of light are only half the actual bending of light (as observed and predicted by GR).
Matterwave said:Can you kindly refresh my memory on why Newtonian physics would predict a bending of light even if we say that it is massless?
I only remember F=GMm/r^2 which would obviously be 0 if one of the m's were 0.
Matterwave said:Sounds very iffy to me.
Getting that formula g=GM/r^2 is done by doing: mg=GMm/r^2 is it not?
A.T. said:You can get the acceleration by directly observing the trajectories, which turn out to be independent of m. The formula for the gravitational force is derived from this. You have to keep in mind that force is rather an abstract concept, while trajectories/acceleration are observed directly.
P3X-018 said:Gravity doesn't affect massless particles in the classical mechanics.
Vanadium 50 said:Pierre-Simon Laplace would be very surprised to read that. He proposed black holes - bodies so massive that even light could not escape - and his argument relied on the universal acceleration of bodies in free fall.
This was in 1799.
This really is the key point.A.T. said:You can get the acceleration by directly observing the trajectories, which turn out to be independent of m. The formula for the gravitational force is derived from this. You have to keep in mind that force is rather an abstract concept, while trajectories/acceleration are observed directly.
So how much force do I need to bend the trajectory of a massless particle?P3X-018 said:You can't bend a trajectory without a force.
Acceleration is an observed quantity. Force is just a derived concept that makes sense for massive particles only.P3X-018 said:The acceleration is just the result of the force between the bodies attracting each other.
Newtonian gravity accelerates objects independently of their mass. That is the observed reality. From that you can derive F=GMm/r^2 via F=ma, but only for massive objects. For massless objects F=ma is not applicable, and so neither is F=GMm/r^2. Therefore you cannot use F=GMm/r^2 to show that massless objects are not affected by Newtons gravity.P3X-018 said:Gravity doesn't affect massless particles in the classical mechanics.
Yes, it's natural to justify it using limits--since an object's acceleration in a gravitational field can be shown to be independent of its own mass for any nonzero mass, this is obviously going to be true in the limit as a particle's mass approaches zero.Matterwave said:Sounds very iffy to me.
Getting that formula g=GM/r^2 is done by doing: mg=GMm/r^2 is it not? In which case, you cancel the two lower case m's and you get g. You can't do that if the lower case m is 0, that's dividing by zero and is a classic way of getting ridiculous results.
I suppose you could justify it using limits...
For Newtonian gravity, with rubber sheet representing the gravitational potential, this works as an analogy. But it doesn't' explain the gravity model of General Relativity. See this thread:JanClaesen said:If you put a heavy bowling ball on a trampoline it will roll to its center and sink in a way that if you put some tennisballs on the trampoline that they will roll to the bowling ball, this we experience as gravity. Is this a valid comparision?
The rubber sheet represents 2 spatial dimensions, omitting 1 spatial and 1 time dimension. But the time dimension is crucial to explain gravity in GR. So it is better to omit 2 spatial dimensions:JanClaesen said:The author says the example is in 2D, but if the ball sinks, isn't that 3D? (Is that perhaps why a fourth dimension is added in relativity?)
Newton's gravitation fails us when dealing with extremely large or extremely small objects, or when dealing with objects moving at very high speeds.
An example of when Newton's gravitation fails us is when trying to explain the orbit of Mercury around the Sun. Newton's laws cannot fully account for the observed discrepancies in Mercury's orbit, which were later explained by Einstein's theory of general relativity.
Einstein's theory of general relativity takes into account the effects of gravity on the fabric of space-time, while Newton's theory only considers the force of gravity between objects. This allows for a more accurate explanation of the motion of objects in extreme conditions.
Understanding when Newton's gravitation fails us is important because it allows us to accurately describe and predict the behavior of objects in the universe. It also helps us to develop more advanced theories and technologies, such as space travel and GPS systems.
Yes, Newton's theory of gravitation is still relevant in modern science. It is still used in many practical applications and provides a good approximation for most everyday situations. However, it has been expanded upon and improved by more advanced theories, such as Einstein's theory of general relativity, to explain phenomena that Newton's theory cannot.