The discussion revolves around the concept of terminal velocity in a vacuum, particularly focusing on whether there is a maximum velocity an object can achieve while falling in a gravitational field without atmospheric resistance. Participants explore the implications of gravitational strength and the nature of acceleration in relation to relativistic effects.
Participants express multiple competing views regarding the nature of terminal velocity in a vacuum and the implications of gravitational strength on maximum velocity. The discussion remains unresolved with differing interpretations of gravitational effects and relativistic principles.
Participants acknowledge that the scenario of falling from infinity is highly artificial and that gravitational force diminishes with distance, which complicates the discussion of terminal velocity in a vacuum.
Doc Al said:Not exactly sure what you mean. If you mean: Imagine the Earth with no atmosphere and you dropped an object from infinity (ignoring other masses, of course)? Then the mass and radius of the Earth would determine the speed with which the object hits the surface.
Yes. Your speed with respect to the Earth will never exceed the speed of light.tkav1980 said:Is there a point where the strength of Earth's gravity can no longer increase your velocity? Is there an upper speed limit relative to the strength of the gravitational pull from a given body?
Doc Al said:Yes. Your speed with respect to the Earth will never exceed the speed of light.
Doc Al said:Let's leave general relativity aside. You've created an artificial situation, a constant gravitational field that extends to infinity. (An infinitely high hill.) So that gravitational potential energy is the source of the energy.
From special relativity, we know that as the the speed of an object approaches the speed of light, it takes more and more energy to attain an increase in speed. It would require 'infinite' energy to reach the speed of light itself.
It's not that gravity (or the resulting proper acceleration) depends on the speed, but the effect of that acceleration does.dtyarbrough said:Where is it written that gravity, the force that accellerates all matter equally, regardless of mass, is in any way dependent on the speed and/or increased mass of the object.
Only if you ignore the lessons of special relativity. Speeds don't add like they do in Newtonian physics. Even though the proper acceleration remains 9.8 m/s2 (say), with each succeeding second, the speed increase with respect to an outside frame (the earth) is less. It never reaches the speed of light.It should take approximately 9360 hours to reach the speed of light at a rate of 9m/sec/sec.
tkav1980 said:Imagine being infinitely far away form the Earth yet still able to experience its gravity with the same force as it is felt on earth. You are also in a vacuum falling towards earth. Since you are infinitely far away you will never reach it. Is there a point where the strength of Earth's gravity can no longer increase your velocity? Is there an upper speed limit relative to the strength of the gravitational pull from a given body?
It's worth mentioning that the origin of terminal velocity is an essentially constant force in one direction (gravity) opposed by a force in the opposite direction which increases with speed (air resistance). The two balance at exactly one speed. That speed is the "terminal velocity".tkav1980 said:I am curious if there is a terminal velocity for an object in free fall in a gravitational field based on the strength of that field. If I was falling to Earth and there was no atmosphere, and I had infinite time to fall(Meaning I'd never actually reach the surface) would the strength of Earth's gravity determine the maximum velocity I could achieve?