Yes if the moon fell on earth it would definetly produce a noticable magnetic field.
Gravitational force is caused by acceleration due to gravity and an objects mass. Gravitational force is the same as an object's weight. Gravitational force is something scientists try to measure. Physics is an area of science where people study gravitational force. Gravitational force is important in terms of the way planets orbit the sun in our solar system.
lets say if you drop a boulder and A PIECE OF PAPER THEY WILL FALL AT THE SAME TIME IN A VACUUM SEALED CHAMBER
Mass, not density, and the closeness of objects, affects an object's gravitational pull. Density is not dependent on an object's size, but mass is. The more massive an object, and/or the closer an object is to another, the greater its gravitational pull.
similarities between these 2 force are thatboth of these forces are directly proportional to the product of masses and inversely proportional to the square of distance between the two massesand the differences are that coulombsforce could be repulsive or attractive but gravitational force is only attartive one and gravitational constant is smaller than electric constant
the objects fall to the ground
Gravitational force
Gravitational potential energy
Black holes might be seen by their Hawking radiation, but that radiation is expected to be extremely weak. It is more likely that a black hole would be seen:By matter falling into it. Before reaching the event horizon, the tremendous acceleration will produce electromagnetic waves (X-rays, for example). By observing the movement of other objects around the black hole.By gravitational lensing. All of these depend on the gravity of the black hole.Black holes might be seen by their Hawking radiation, but that radiation is expected to be extremely weak. It is more likely that a black hole would be seen:By matter falling into it. Before reaching the event horizon, the tremendous acceleration will produce electromagnetic waves (X-rays, for example).By observing the movement of other objects around the black hole.By gravitational lensing. All of these depend on the gravity of the black hole.Black holes might be seen by their Hawking radiation, but that radiation is expected to be extremely weak. It is more likely that a black hole would be seen:By matter falling into it. Before reaching the event horizon, the tremendous acceleration will produce electromagnetic waves (X-rays, for example).By observing the movement of other objects around the black hole.By gravitational lensing. All of these depend on the gravity of the black hole.Black holes might be seen by their Hawking radiation, but that radiation is expected to be extremely weak. It is more likely that a black hole would be seen:By matter falling into it. Before reaching the event horizon, the tremendous acceleration will produce electromagnetic waves (X-rays, for example).By observing the movement of other objects around the black hole.By gravitational lensing. All of these depend on the gravity of the black hole.
When falling to the ground (or even just in the air), the acceleration of an object depends on the gravitational pull of the object it is falling towards. Here on earth, all things fall relative to the earth which causes an acceleration of 9.81 m/s^2
Macro objects can attract through gravitational or electromagnetic force. Repulsion can be observed only for later ones. Nature of gravitational force is not understood yet. But electromagnetic attraction is due to certain magnetic, or/and static or/and electric charge.
Because the acceleration of objects free falling is consistent anywhere on earth, one can conclude that inertial and gravitational mass are equal.
terminal velocity
Objects that can fall have a gravitational potential energy! so the answer is A.
The electromagnetic forces holding molecules together within the table provide a mesh like structure that prevents the molecules of other objects protruding (or falling) through it!
Gravitational attraction.
If the objects are the same distance apart (center to center), then the gravitational force between two less massive objects will be less than the gravitational force between two more massive objects.
Objects of greater mass have more gravitational pull.