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Gravity is a constant value, and therefore is not dependent on the extrinsic properties of an object.
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Very nice.
-- The more mass in an object, the more gravitational force draws it towards the Earth.
-- But the more mass it has, the more force it takes to accelerate it at any rate you name.
-- So the more gravitational force there is pulling it down, the more force it takes to accelerate it.
-- Those conditions work exactly against each other, so that every mass falls with the same acceleration.
What else can I help you with?
Is the acceleration the same on an object that is drop or when its thrown?
No, the acceleration is not the same for an object that is dropped and an object that is thrown. When an object is dropped, it experiences a constant acceleration due to gravity. When an object is thrown, its acceleration can vary depending on factors such as the initial velocity and direction.
As a freely falling object speeds up what is happening to its acceleration due to gravity?
Its acceleration due to gravity is constant. The acceleration is equal to the object's change in speed every second. I've tried to illustrate the constantly-increasing falling speed in my diagram below.
Are acceleration due to gravity on small stone and big stone equal?
Yes, the acceleration due to gravity on both small and big stones is equal because it depends only on the mass of the Earth and the distance from its center. The mass of the stone does not affect the acceleration due to gravity.
What is the Effect of increasing the object's mass of the acceleration due to gravity?
On earth, the mass of an object has no effect whatsoever on its acceleration due to the force of gravity. All objects fall with the same acceleration, regardless of their mass. Any observed difference is due entirely to air resistance.
Is an object in free fall with less air resistance fall with a greater acceleration?
No, an object in free fall experiences the same acceleration due to gravity regardless of its shape or size. Air resistance does not affect the acceleration due to gravity acting on the object.
Is the acceleration the same on an object that is drop or when its thrown?
No, the acceleration is not the same for an object that is dropped and an object that is thrown. When an object is dropped, it experiences a constant acceleration due to gravity. When an object is thrown, its acceleration can vary depending on factors such as the initial velocity and direction.
As a freely falling object speeds up what is happening to its acceleration due to gravity?
Its acceleration due to gravity is constant. The acceleration is equal to the object's change in speed every second. I've tried to illustrate the constantly-increasing falling speed in my diagram below.
Are acceleration due to gravity on small stone and big stone equal?
Yes, the acceleration due to gravity on both small and big stones is equal because it depends only on the mass of the Earth and the distance from its center. The mass of the stone does not affect the acceleration due to gravity.
What is the Effect of increasing the object's mass of the acceleration due to gravity?
On earth, the mass of an object has no effect whatsoever on its acceleration due to the force of gravity. All objects fall with the same acceleration, regardless of their mass. Any observed difference is due entirely to air resistance.
Is an object in free fall with less air resistance fall with a greater acceleration?
No, an object in free fall experiences the same acceleration due to gravity regardless of its shape or size. Air resistance does not affect the acceleration due to gravity acting on the object.
What happens to acceleration if the mass is increased and due to gravity?
If the mass is increased and gravity remains constant, the acceleration will decrease. This is because the force acting on the object remains the same due to gravity, but as the mass increases, the object will experience a greater resistance to acceleration.
Is the acceleration due to gravity dependent on the mass of an object?
No, the acceleration due to gravity is constant regardless of the mass of an object. All objects near Earth's surface experience the same acceleration due to gravity, which is approximately 9.8 m/s^2.
Explain the relationship between the acceleration due to gravity of an falling object and the slope?
The force of gravity on object can differ because of its slope. An object can pick up quick acceleration at a steep slope due to the force of gravity than normal slopes. We say that gravity is force of attraction between the body and the surface of the earth. at a slope gravity attracts the object to itself. The gravitational force is 9.8N. when gravity attracts the object to itself than for sure the object will gain acceleration but the acceleration rate of the object will differ by the slope that it has been pulled.
What is the acceleration of the same object in the above question when it is descending?
The acceleration of the object when descending will be equal to the acceleration due to gravity, which is approximately 9.81 m/s^2 near the surface of the Earth.
Why is the mass of an object same on the moon as it is on earth but the weight is different?
Mass is the amount of matter in an object. It does not change based on gravity. Weight is the force an object exerts 'downward' due to gravitational acceleration. Force = (mass)*(acceleration). Acceleration due to gravity is less on the Moon than on Earth.
Why is the acceleratoin due to gravity the same for all objects?
-- The more mass an object has, the more gravitational force there is betweenit and the Earth.-- But the more mass an object has, the more force is required to accelerate it.-- The relationship between how much gravitational force there is and how much forceis required trades off just right, so that every mass has the same acceleration.
The speed at which an object falls and the acceleration at which it falls are always the same value?
The speed at which an object falls and the acceleration at which it falls are not the same value. The acceleration due to gravity is constant at about 9.8 m/s^2 near the surface of the Earth, but the speed of an object can change as it falls depending on factors such as air resistance.
