oragami said:but i ment if the sphere was spinning and like a gas was in it, if most of the gas would travel towards the centre. Please advice
NO, it wouldn't. It would travel toward the circumference. That was mathman's point.oragami said:but i ment if the sphere was spinning and like a gas was in it, if most of the gas would travel towards the centre. Please advice
People walking on the inside wall of the spinning spacecraft (heads pointed toward the axis of rotation) would feel a force pushing them against the space craft. Than can "simulate" gravity but will not be exactly the same. For example, in all but an immense space craft, coriolis forces would be evident.math_04 said:Is that the whole notion behind artificial gravity in a spacecraft ? A spinning spacecraft can reproduce the effects of gravity if I am not mistaken?
Chronos said:A spinning fluid mass would resemble a galaxy in deep space. Gravity limits the effects of centripetal force.
In a galaxy the centripetal force is gravity.Wallace said:I have no idea what you are trying to say? In a galaxy gravity is what provides the centripedal force that keeps it together??
oragami said:What I'm trying to get at is this, can a spinning framework of rings build enough centripetal force to keep a mass of liquid at the centre of the frame work? And if so what would be the relationship and conditions that would have to be met?
Really need help:|
raknath said:Does this amount to saying that randomly circulating gas molecules cannot be ?bound? by the centripetal force?
How does gravity keep ?them? together, is gravity stronger than centripetal force?
Several levels of issues here:raknath said:So is the difference in behavior mainly due to the atomic freedom that exists in gasses
Does this amount to saying that randomly circulating gas molecules cannot be bound by the centripetal force?
How does gravity keep them together, is gravity stronger than centripetal force?
raknath said:Consider a box with some gas and a lot of holes(very hypothetically)
Let us say i send the box into revolutions, now by what we have seen the gas would escape out of the holes, as the box rotates?
Now however if the gas is gravitationally bound like it is for say jupiter, the gas does not escape, i mean why is this any different? Does this mean that gravity influences gas molecules differently than it is affected by centripetal force?
Better: Gravity is a central force. Centripetal force is a kinematical rather than dynamical concept. This page, http://encyclopedia.stateuniversity.com/pages/3970/centripetal-force.html explains central versus centripetal versus centrifugal forces in a nice, simple manner.Janus said:A centripetal force is one that acts toward the center, so gravity is a centripetal force.
What centripetal force? You are acting as if centripetal force is something real in and of itself. It isn't. The real (i.e., physical) force in your rotating box is the electrostatic repulsion between the surface of the box and the gas molecules that hit it. The mass of the gas itself is insignificant. The real force in the case of Jupiter is the mass of all the stuff that comprises Jupiter. Compare this to the gas in a box situation. The gravitational force exerted by the gas on a gas particle near the surface of the box (or anywhere inside the box) is immeasurably small.raknath said:Now however if the gas is gravitationally bound like it is for say jupiter, the gas does not escape, i mean why is this any different? Does this mean that gravity influences gas molecules differently than it is affected by centripetal force?
Janus said:When you put holes in the box, you have areas where there is no centripetal force to contain the gas and it escapes.
D H said:What centripetal force? You are acting as if centripetal force is something real in and of itself. It isn't. The real (i.e., physical) force in your rotating box is the electrostatic repulsion between the surface of the box and the gas molecules that hit it. The mass of the gas itself is insignificant. The real force in the case of Jupiter is the mass of all the stuff that comprises Jupiter. Compare this to the gas in a box situation. The gravitational force exerted by the gas on a gas particle near the surface of the box (or anywhere inside the box) is immeasurably small.
raknath said:Why so?
The holes are covered with air which in turn would be atttracted towards the center so there should be a force the air exerts towards the center, won't it?
However the reaction force of th gas still wins, how?
JCOX said:Yes...Theoreticaly this is possible. For simplisity sake take for example a ring and contain within it two elements... one a gas and other liquid. Let the gas be significantly "heavier" than the fluid. When spinning centripetal force would pull the heavy gas to the outside and leave the fluid (lightier) in the center...Is this even what you are asking?
No, centripetal force and gravity are two separate forces that have different origins and effects. Centripetal force is the force that keeps an object moving in a circular path, while gravity is the force that pulls objects towards each other due to their mass.
No, Earth's gravity is caused by its mass and the curvature of spacetime, as explained by Einstein's theory of general relativity. While centripetal force does play a role in keeping objects in orbit around the Earth, it is not the primary force responsible for Earth's gravity.
Yes, centripetal force can be used to simulate gravity in a rotating space habitat. By creating a circular motion, objects inside the habitat will feel a centrifugal force that is perceived as a gravitational force. However, this is not true gravity and objects will not behave exactly as they do on Earth.
No, gravity is a fundamental force that is much stronger than centripetal force. For example, the centripetal force that keeps the Moon in orbit around Earth is only about 1/6th of the force of gravity between the two objects.
No, centripetal force and gravity are independent forces and cannot be manipulated to change the strength of gravity between two objects. However, the effects of gravity can be altered through other means such as changing an object's mass or distance from another object.