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As objects get heavier, two different things are happening: they experience a greater gravitational attraction to the Earth, but they also have more inertia, requiring greater force in order to accelerate them. As it turns out, these two things cancel each other out exactly. That is why, excluding air resistance, everything falls at exactly the same rate, no matter how heavy or light a given falling object may be. Another way of putting this is that gravitational mass and inertial mass are the same. Physicists are not entirely sure why they are the same, and this remains an important question of theoretical physics.
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Do objects of same mass but of different shapes fall at the same rate?
Yes. Also, objects of different mass, whether or not they have the same shape. With normal Earth gravity, i.e., near the Earth's surface, they will accelerate at about 9.8 meters/second2. This assumes that air resistance can be neglected; once air resistance becomes significant, the acceleration will be less.
How do all objects fall?
All objects fall towards the center of the Earth due to gravity. The rate at which objects fall is determined by their mass and the gravitational force acting upon them. In the absence of air resistance, all objects would fall at the same rate regardless of their mass.
Why do objects on Earth fall at different rates?
Objects on Earth fall at different rates due to the influence of gravity. The rate at which an object falls is determined by its mass and the force of gravity acting upon it. Heavier objects experience a greater gravitational force, causing them to fall faster than lighter objects. Additionally, air resistance can also affect the rate at which objects fall, with larger and more aerodynamic objects experiencing less air resistance and falling faster.
Why do objects fall towards the center of the earth because of what?
Objects fall towards the center of the Earth due to the force of gravity. Gravity is an attractive force between all objects with mass, pulling them towards each other. The Earth's mass creates a gravitational pull that causes objects to accelerate towards its center.
Do all objects fall toward the end of the earth?
Yes, objects fall towards the center of the Earth due to gravity. This is true regardless of the object's size, mass, or shape.
Who found (discovered) that objects of different mass and weight fall at the same rate?
Who found (discovered) that objects of different mass and weight fall at the same rate
Do objects of same mass but of different shapes fall at the same rate?
Yes. Also, objects of different mass, whether or not they have the same shape. With normal Earth gravity, i.e., near the Earth's surface, they will accelerate at about 9.8 meters/second2. This assumes that air resistance can be neglected; once air resistance becomes significant, the acceleration will be less.
How do all objects fall?
All objects fall towards the center of the Earth due to gravity. The rate at which objects fall is determined by their mass and the gravitational force acting upon them. In the absence of air resistance, all objects would fall at the same rate regardless of their mass.
Why do objects on Earth fall at different rates?
Objects on Earth fall at different rates due to the influence of gravity. The rate at which an object falls is determined by its mass and the force of gravity acting upon it. Heavier objects experience a greater gravitational force, causing them to fall faster than lighter objects. Additionally, air resistance can also affect the rate at which objects fall, with larger and more aerodynamic objects experiencing less air resistance and falling faster.
Why do objects fall towards the center of the earth because of what?
Objects fall towards the center of the Earth due to the force of gravity. Gravity is an attractive force between all objects with mass, pulling them towards each other. The Earth's mass creates a gravitational pull that causes objects to accelerate towards its center.
Do all objects fall toward the end of the earth?
Yes, objects fall towards the center of the Earth due to gravity. This is true regardless of the object's size, mass, or shape.
What is the force called that makes all objects fall at different speed?
That's called the "force of imagination".In the absence of air, all objects fall with the same acceleration. At equal times after the drop, all objectsare falling at the same speed.
What force makes objects fall to earth?
The force of gravity is what makes objects fall to Earth. Gravity is a force of attraction between all objects with mass, pulling them towards each other. On Earth, gravity pulls objects towards the center of the planet, causing them to fall downwards.
What happens when objects objects of different mass are dropped under the same gravitational conditions?
When objects of different mass are dropped under the same gravitational conditions, they will fall at the same rate and hit the ground simultaneously. This is due to the principle of gravitational acceleration, which states that all objects, regardless of their mass, will accelerate towards the Earth at the same rate (9.8 m/s^2). This phenomenon was famously demonstrated by Galileo with his experiment at the Leaning Tower of Pisa.
Why do objects fall towards the earth?
Objects fall towards the Earth due to the force of gravity. Gravity is the natural force of attraction between objects with mass, pulling them towards each other. The Earth's gravity is what causes objects to accelerate towards it when dropped.
Do objects that fall toward Earth fall faster and faster?
Objects that fall towards Earth do not fall faster and faster. In a vacuum, all objects fall at the same rate, regardless of their mass. This is known as the principle of universal gravitation and was first demonstrated by Galileo.
Do objects of the same mass of different shapes fall at the same rate?
Yes. Also, objects of different mass, whether or not they have the same shape. With normal Earth gravity, i.e., near the Earth's surface, they will accelerate at about 9.8 meters/second2. This assumes that air resistance can be neglected; once air resistance becomes significant, the acceleration will be less.
