That's because the gravitational force isn't the only force acting, in this case.
momentum i think
Yes, and you can do even better than that.Weight IS the gravitational force on a mass.
Magnitude is a scientific way of saying size or number. The gravitational force is the force (measured by Newtons (N)) acting on an object. On earth, the gravitational force is 9.81 Newtons, this can be commonly rounded to 9.8 or even 10, depending on the accuracy required. In laymen's terms, the magnitude of the gravitational force is simply the strength of gravity acting on an object.
Gravitational force does not change your mass. Mass is the same when you are floating in the weightlessness of space, but your mass when put into a gravitational field creates your weight. On Earth, Earth's gravity (gravitational force) pulls on your mass, creating your weight. The mass of an object determines its gravitational pull. A object with a lot of mass like the Earth has a lot of gravitational force/pull -- the force we call gravity. So, your body has a gravitational force, it's just so small, because your mass is small, it isn't noticeable.
Gravity. Even though we notice the effect of gravity every day it is the weakest of the fundamental forces. However you could argue that the strong nuclear force is the weakest acting between these two bodies, because they are too far away from each other for this force to act.
Yes, there is g-force present in space. G-force refers to the force of gravity acting on an object, and even in space, objects are still affected by the gravitational pull of celestial bodies like planets and stars.
Since there is more mass in the uranium nucleus, there would be a proportionally stronger gravitational force in the uranium nucleus. However, the gravitational force is the weakest force, and it is followed in scale by the weak atomic force, the electromagnetic force, and the strong atomic force, which are many orders of magnitude greater, so, in effect, the gravitational force does not even count in the vicinity of the nucleus.
Yes. An object is weightless if gravity is the only force acting on it. (for example, a ball falling in a vacuum) There is no true "weightlessness", because, even if two masses are separated by billions of light years, there is still a gravitational attraction force. There is a distance at which this cannot be felt anymore, but there is still a force.
A black hole has the greatest force of gravitational attraction. Even light rays can't escape.
A black hole has the greatest force of gravitational attraction. Even light rays can't escape.
Gravitational force is a non-contact force, meaning it can act on objects even when they are not in direct physical contact with each other. This force is based on the mass of objects and their distance from each other, rather than requiring direct contact.
A black hole is an object with such a strong gravitational force that not even light can escape from it, due to its extremely dense and compact nature.