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Does the earth attract objects because they have a large mass?
Yes, the Earth's gravitational force attracts objects towards its center. This force is proportional to the mass of the objects and the distance between them, causing objects with larger masses to experience a stronger gravitational pull towards Earth.
What are large objects that move around a star?
Planets, moons, asteroids, and comets are some examples of large objects that move around a star, such as the Sun in our solar system. These objects orbit the star due to gravitational forces and can vary in size and composition.
Why are objects on earth attracted o the earth but not to each other?
Objects on Earth are attracted to the Earth due to its massive gravitational pull, which is a result of its large mass. While all objects do exert gravitational forces on each other, these forces are usually negligible compared to the Earth's gravitational pull, especially for smaller objects. Therefore, the dominant force acting on them is the Earth's gravity, making them fall towards it rather than being significantly attracted to each other.
How does gravitational force compare between objects that have small masses and objects that have large masses?
It will be larger between the large objects. This force is equal to the universal gravitational constant times the two masses of the objects, all divided by the square of the distance apart the objects are.
Is there more gravitational force between objects with small masses or objects with large masses?
There is more gravitational force between objects with large masses compared to objects with small masses, as gravitational force increases with the mass of the objects. This is described by Newton's law of universal gravitation, which states that the force of gravity is directly proportional to the product of the masses of the two objects and inversely proportional to the square of the distance between them.
Does the earth attract objects because they have a large mass?
Yes, the Earth's gravitational force attracts objects towards its center. This force is proportional to the mass of the objects and the distance between them, causing objects with larger masses to experience a stronger gravitational pull towards Earth.
What are large objects that move around a star?
Planets, moons, asteroids, and comets are some examples of large objects that move around a star, such as the Sun in our solar system. These objects orbit the star due to gravitational forces and can vary in size and composition.
Why are objects on earth attracted o the earth but not to each other?
Objects on Earth are attracted to the Earth due to its massive gravitational pull, which is a result of its large mass. While all objects do exert gravitational forces on each other, these forces are usually negligible compared to the Earth's gravitational pull, especially for smaller objects. Therefore, the dominant force acting on them is the Earth's gravity, making them fall towards it rather than being significantly attracted to each other.
What are Lagrangian points and how do they relate to the stability of objects in space?
Lagrangian points are specific locations in space where the gravitational forces of two large bodies, such as a planet and its moon, create a stable equilibrium for smaller objects. These points allow objects to maintain their position relative to the larger bodies without drifting away or being pulled in. The stability of objects at Lagrangian points is due to the balance of gravitational forces at those locations.
How does gravitational force compare between objects that have small masses and objects that have large masses?
It will be larger between the large objects. This force is equal to the universal gravitational constant times the two masses of the objects, all divided by the square of the distance apart the objects are.
What are the characteristics oc non contact forces?
Characteristics of Non-Contact Force:a)Are equal and opposite.b)Depend upon the distance between the two objects.c)Depend upon the medium between the two objects for electrical and magnetic forcesbut not gravitational forces.By Khan.shariq3@facebook.com
How does the gravitational force between 2 objects that have small masses compare to the gravitational force between large objects?
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.
Which objects have the most gravitational force?
the objects with the greatest mass and the ones that are closest to other objects
Is there more gravitational force between objects with small masses or objects with large masses?
There is more gravitational force between objects with large masses compared to objects with small masses, as gravitational force increases with the mass of the objects. This is described by Newton's law of universal gravitation, which states that the force of gravity is directly proportional to the product of the masses of the two objects and inversely proportional to the square of the distance between them.
When a large objectsvmove closer together the force of gravity becomes?
Stronger, as the gravitational force between two objects is directly proportional to the product of their masses and inversely proportional to the square of the distance between them. By moving closer together, the distance between the objects decreases, increasing the gravitational force between them.
Why would you rip apart in a black hole?
Immense gravitational forces would cause large mass objects to be stretched and compacted as it nears the black hole. Whatever is closer gets pulled in first, providing for unequal gravitational attraction.
What would be the greatest force of gravitational attraction?
The force of gravitational attraction between two objects is strongest when their masses are large and they are very close together. For example, a planet and a star or two massive celestial bodies would experience a strong gravitational attraction between them.
