The Newtonian model of the universe is often described as a clock work universe; everything works in a way that matches our everyday experience. Gravity is a force pulling everything together, time marches forward in a consistent manner for everyone, and a few elegant principles can explain things as divergent as a falling apple or the orbit of the moon. It's a comfortable place, easy to get your head around. Unfortunately, it isn't the universe we inhabit. So along came Einstein and the relativistic universe. Suddenly, gravity is a curvature of space-time, time itself is relative, and the only constant is the speed of light. This is a universe not nearly so consistent with everyday experience. It's a universe where thing like black holes and the infamous twins paradox can occur. And it's a lot harder to wrap your head around.
My purpose here is to propose a thought experiment that I hope will show that the Newtonian universe may not actually be all that neat and tidy and can lead to some rather paradoxical results itself; results that conveniently go away if we accept some fundamental premises of relativity. Of course I must preface this by saying that I am not a physicist and may be skating on very thin ice. But it was either post it and get some feedback or else keep bouncing it around in my brain in an annoyingly distracting fashion. So feel free to comment, correct me, or just tell me I'm all wet.
I'll start with two spaceships (Spaceship One and Spaceship Two) which are coasting along in nice flat Newtonian space at an equal velocity. Spaceship One is moving from point A to point B, Spaceship Two from point X to point Y. The distance between A and B is equal to the distance between X and Y. So they will both make their respective journeys in an equal period of time. The only way one could cover the distance faster than the other is for some force to be applied to it so that it accelerates and obtains a greater velocity. So far, so obvious.
Now, I'll introduce a planetoid. This particular planetoid is plopped down right in the middle of the path of Spaceship Two dead center between point X and point Y. Luckily for the crew of Spaceship Two, the planetoid has a hole drilled all the way through it big enough to let a spaceship fly right through. I will also note that Spaceship One is far enough away from the planetoid that the gravitational effect on it is negligible.
The behavior of Spaceship One is pretty simple. It just costs along at a constant velocity from point A to point B. The behavior of Spaceship Two is more complex. The planetoid exerts a gravitation tug on the ship that causes it to accelerate. This acceleration increases until the ship reaches the mouth of the tunnel at which point it begins to diminish until the ship reaches the center where the acceleration reaches zero (and the velocity of the ship reaches it's maximum). The acceleration then reverses and becomes negative acceleration reducing the velocity of the ship so that by the time it reaches point Y on the other side, the velocity of Spaceship Two is exactly the same as it was at point X.
If we graph the velocity of our two ships with respect to time over the course of the journey, the graph for Spaceship One is a flat line while the graph for Spaceship Two is a bell curve with it's highest point corresponding to the moment the ship passed through the center of the planetoid and it's lowest values corresponding to the end points at X and Y. Since these end point velocities are equal to the velocity of Spaceship One, it is evident that over the whole course of the trip, Spaceship Two was moving at a greater velocity than Spaceship One. So naturally, you would conclude that Spaceship Two will cover the distance from X to Y in less time than it takes Spaceship One to get from A to B. But this "obvious" conclusion has a problem: what was the force that allowed Spaceship Two to outrace it's sister ship? The planetoid certainly exerted a gravitational force on the ship. But the net acceleration for that force over the entire course of the trip sums up to zero. If it didn't, Ship Two would not have arrived at point Y with exactly the same velocity it had at point X. So did Ship Two actually get to point Y sooner than Ship One reached B? And if not, how do we account for all that extra velocity?
In a Newtonian universe this would seem to be a paradox. In a relativistic universe, however, it really isn't a problem. Gravity curves space. The path from X to Y for Spaceship Two is actually longer than the path from A to B for Spaceship One because Spaceship Two is plunging through a gravity well. It has to move faster just to get to point Y at the same time as Spaceship One reaches point B.
My purpose here is to propose a thought experiment that I hope will show that the Newtonian universe may not actually be all that neat and tidy and can lead to some rather paradoxical results itself; results that conveniently go away if we accept some fundamental premises of relativity. Of course I must preface this by saying that I am not a physicist and may be skating on very thin ice. But it was either post it and get some feedback or else keep bouncing it around in my brain in an annoyingly distracting fashion. So feel free to comment, correct me, or just tell me I'm all wet.
I'll start with two spaceships (Spaceship One and Spaceship Two) which are coasting along in nice flat Newtonian space at an equal velocity. Spaceship One is moving from point A to point B, Spaceship Two from point X to point Y. The distance between A and B is equal to the distance between X and Y. So they will both make their respective journeys in an equal period of time. The only way one could cover the distance faster than the other is for some force to be applied to it so that it accelerates and obtains a greater velocity. So far, so obvious.
Now, I'll introduce a planetoid. This particular planetoid is plopped down right in the middle of the path of Spaceship Two dead center between point X and point Y. Luckily for the crew of Spaceship Two, the planetoid has a hole drilled all the way through it big enough to let a spaceship fly right through. I will also note that Spaceship One is far enough away from the planetoid that the gravitational effect on it is negligible.
The behavior of Spaceship One is pretty simple. It just costs along at a constant velocity from point A to point B. The behavior of Spaceship Two is more complex. The planetoid exerts a gravitation tug on the ship that causes it to accelerate. This acceleration increases until the ship reaches the mouth of the tunnel at which point it begins to diminish until the ship reaches the center where the acceleration reaches zero (and the velocity of the ship reaches it's maximum). The acceleration then reverses and becomes negative acceleration reducing the velocity of the ship so that by the time it reaches point Y on the other side, the velocity of Spaceship Two is exactly the same as it was at point X.
If we graph the velocity of our two ships with respect to time over the course of the journey, the graph for Spaceship One is a flat line while the graph for Spaceship Two is a bell curve with it's highest point corresponding to the moment the ship passed through the center of the planetoid and it's lowest values corresponding to the end points at X and Y. Since these end point velocities are equal to the velocity of Spaceship One, it is evident that over the whole course of the trip, Spaceship Two was moving at a greater velocity than Spaceship One. So naturally, you would conclude that Spaceship Two will cover the distance from X to Y in less time than it takes Spaceship One to get from A to B. But this "obvious" conclusion has a problem: what was the force that allowed Spaceship Two to outrace it's sister ship? The planetoid certainly exerted a gravitational force on the ship. But the net acceleration for that force over the entire course of the trip sums up to zero. If it didn't, Ship Two would not have arrived at point Y with exactly the same velocity it had at point X. So did Ship Two actually get to point Y sooner than Ship One reached B? And if not, how do we account for all that extra velocity?
In a Newtonian universe this would seem to be a paradox. In a relativistic universe, however, it really isn't a problem. Gravity curves space. The path from X to Y for Spaceship Two is actually longer than the path from A to B for Spaceship One because Spaceship Two is plunging through a gravity well. It has to move faster just to get to point Y at the same time as Spaceship One reaches point B.
I guess I'll just have to ignore it and hope it goes away. 
