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No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.
Comparable with what? You can compare the electrical force with other forces. For example, if you compare it with gravity, it turns out that both are inverse-square laws. While gravity acts on ANY mass, the electrical force only acts on electrically charged objects. And while gravity is always attractive, the electrical force can be both attractive and repulsive.
Both have the concept of variation of force inversely with the square of the distance. But in case of coulomb we have electric charges and in case of newton's gravitation law we have masses. Coulomb's force can be either attractive and repulsive where as Newton's is only attractive
No force "acts on the force of gravity". Rather, both gravity and other forces - such as drag - will act on objects.
Gravity attracts all mass, period. More massive objects have higher gravity, but even low masses will attract.
No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.No. Magnetism and gravity are quite different forces. For starters, gravity acts on all masses, and the amount of force depends only on the masses and the distance - and it is always attractive. The magnetic force depends on the material, and it can be both attractive and repulsive, depending on the orientation.
Comparable with what? You can compare the electrical force with other forces. For example, if you compare it with gravity, it turns out that both are inverse-square laws. While gravity acts on ANY mass, the electrical force only acts on electrically charged objects. And while gravity is always attractive, the electrical force can be both attractive and repulsive.
The electromagnetic force has a longer range of effect than any other force except gravity. It is also the second strongest force. Unlike gravity, it can be both attractive and repulsive.
Gravity between two objects will form a mutually attractive force on both objects, proportional to the product of both masses. Both objects will accelerate toward each other. The force on both objects is the same magnitude, but in opposite directions (it is toward the other object). The amount of acceleration (call it a) is equal to the force divided by the mass of that object. So if one object is very massive (like the Earth, for example) its acceleration will be very small.
Similarities: Both obey an inverse-square law, and, it seems, extend to an arbitrarily far distance.Differences: Gravity is always attractive; gravity is much weaker for individual particles, but because it is always attractive, the overall effect at long distances, and for large masses, is predominant.Similarities: Both obey an inverse-square law, and, it seems, extend to an arbitrarily far distance.Differences: Gravity is always attractive; gravity is much weaker for individual particles, but because it is always attractive, the overall effect at long distances, and for large masses, is predominant.Similarities: Both obey an inverse-square law, and, it seems, extend to an arbitrarily far distance.Differences: Gravity is always attractive; gravity is much weaker for individual particles, but because it is always attractive, the overall effect at long distances, and for large masses, is predominant.Similarities: Both obey an inverse-square law, and, it seems, extend to an arbitrarily far distance.Differences: Gravity is always attractive; gravity is much weaker for individual particles, but because it is always attractive, the overall effect at long distances, and for large masses, is predominant.
Both have the concept of variation of force inversely with the square of the distance. But in case of coulomb we have electric charges and in case of newton's gravitation law we have masses. Coulomb's force can be either attractive and repulsive where as Newton's is only attractive
No force "acts on the force of gravity". Rather, both gravity and other forces - such as drag - will act on objects.
the relationship between buoyant force and gravity is that both definitions have to do with floatation . gravity and buoyant both keep you your object afloat so that it does not submerge
Gravity attracts all mass, period. More massive objects have higher gravity, but even low masses will attract.
Gravity pulls both the fluid and the submerged object downward. The difference between the gravitational attractive forces on the fluid and the submerged object describes the upward (buoyant) force that the fluid exerts on the object.
The gravitational force is only attractive. Electric and magnetic forces can be both attractive and repulsive.
They both create an acceleration.