The equation is F = M A, where F is the Force required to stop the object, M is the object's Mass, and A is its Acceleration. Note that its acceleration in this case is the rate at which you are DE-ACCELERATING the object to stop it.
The force at which the object is travelling.
Oh yes, an object in motion will remain in motion until a force acts on it to change its motion. That is basic physics, which was first described by Isaac Newton. To be more precise, you could also have an object moving forever in an environment that includes gravity, as long as it was moving on a level, completely frictionless surface, which would require magnetic levitation, and of course, no air resistance either, which would require a perfect vacuum (strictly speaking, the surface would not have to be perfectly level either, as long as the variations in height were not too great for the momentum of the object to overcome; it is the frictionless surface which matters). These conditions would be hard to arrange, but in theory it would give you an object that never stops moving. Weight only matters when it results in friction. But it usually does result in friction.
That may refer to an object's mass (units: kilograms), to its momentum (measured in mass x velocity, units are kilogram x meter / second), or to its kinetic energy (measured in joules).
In theory, you can never truly detect if an object is in motion. Although I may travel in my car on the highway, I am not wrong to say that instead of myself moving across the earth, the earth is moving under me! Relativity proves to us that it is impossible to accurately show if an object is in motion or not. From a mathematical perspective, an object that you assume to be moving must be set relative to another object. This is in order to make accurate calculations about the object in question.
The momentum of an object is the product of the object's mass and velocity. This is essentially a measure of how hard it is to stop an object.
You may choke.
The equation is F = M A, where F is the Force required to stop the object, M is the object's Mass, and A is its Acceleration. Note that its acceleration in this case is the rate at which you are DE-ACCELERATING the object to stop it.
The equation is F = M A, where F is the Force required to stop the object, M is the object's Mass, and A is its Acceleration. Note that its acceleration in this case is the rate at which you are DE-ACCELERATING the object to stop it.
Inertia makes it stay still and determines how hard it would be to get it moving
If the motion has stopped before you arrive to investigate the object, then it would be pretty hard to tell. The only way to infer previous motion might be if you had seen it before, and when you return, it's no longer where you left it.
No ALL matter is in motion.
newtons first law. An object in motion stays in motion. Its inertia keeps it going
Oh yes, an object in motion will remain in motion until a force acts on it to change its motion. That is basic physics, which was first described by Isaac Newton. To be more precise, you could also have an object moving forever in an environment that includes gravity, as long as it was moving on a level, completely frictionless surface, which would require magnetic levitation, and of course, no air resistance either, which would require a perfect vacuum (strictly speaking, the surface would not have to be perfectly level either, as long as the variations in height were not too great for the momentum of the object to overcome; it is the frictionless surface which matters). These conditions would be hard to arrange, but in theory it would give you an object that never stops moving. Weight only matters when it results in friction. But it usually does result in friction.
That may refer to an object's mass (units: kilograms), to its momentum (measured in mass x velocity, units are kilogram x meter / second), or to its kinetic energy (measured in joules).
Inertia is a property of matter in which an object resists a change in motion.
friction causes the object in motion to slow down and finally stop. The natural condition of an object that is in motion is to stay in motion. Only friction (the object in contact with another object at rest) will cause the object in motion to lose its motion.
Its density. Its density.
In theory, you can never truly detect if an object is in motion. Although I may travel in my car on the highway, I am not wrong to say that instead of myself moving across the earth, the earth is moving under me! Relativity proves to us that it is impossible to accurately show if an object is in motion or not. From a mathematical perspective, an object that you assume to be moving must be set relative to another object. This is in order to make accurate calculations about the object in question.