If there is no air resistance while falling, the object will accelerate at a constant rate due to gravity. This means it will continue to gain speed as it falls without any force to slow it down.
A falling elephant encounters a greater force of air resistance than a falling feather does. The force of air resistance can't be greater than the weight of the falling object. When the force of air resistance is equal to the weight of the falling object, the object stops accelerating, its falling speed becomes constant, and the force of air resistance doesn't get any bigger. So the force of air resistance against a falling feather can't be greater than the weight of the feather. But the force of air resistance against a falling elephant can be, and undoubtedly is, greater than the weight of a feather.
The weight of a falling object acts downwards, while air resistance acts in the opposite direction of the object's motion. Weight is the force of gravity pulling the object toward the ground, while air resistance is the frictional force that opposes the object's motion through the air.
The main forces acting on a falling object are gravity and air resistance. Gravity pulls the object downward toward the ground, while air resistance, or drag, slows down its descent by pushing upward against it. The net force of gravity minus air resistance determines the object's overall acceleration as it falls.
The object opposes the air and while falling of the object the initial velocity will become zero , and the final velocity will have some value's this is how air will resist the velocity of falling object ...........
You're fishing for "air resistance" but your description isn't correct. Air resistance doesn't "slow" a falling object. Once the object has built up to some particular speed of fall, air resistance prevents it from falling any faster.
A falling elephant encounters a greater force of air resistance than a falling feather does. The force of air resistance can't be greater than the weight of the falling object. When the force of air resistance is equal to the weight of the falling object, the object stops accelerating, its falling speed becomes constant, and the force of air resistance doesn't get any bigger. So the force of air resistance against a falling feather can't be greater than the weight of the feather. But the force of air resistance against a falling elephant can be, and undoubtedly is, greater than the weight of a feather.
Air resistance creates friction and slows a falling object.
Air resistance decreases the acceleration of a falling leaf from a tree. As the leaf falls, air resistance opposes its motion, slowing it down. This results in a lower acceleration compared to if the leaf were falling in a vacuum with no air resistance.
The weight of a falling object acts downwards, while air resistance acts in the opposite direction of the object's motion. Weight is the force of gravity pulling the object toward the ground, while air resistance is the frictional force that opposes the object's motion through the air.
It reduces the acceleration of the falling object due to friction.
As a falling object accelerates through air, its speed increases and air resistance increases. While gravity pulls the object down, we find that air resistance is trying to limit the object's speed. Air resistance reduces the acceleration of a falling object. It would accelerate faster if it was falling in a vacuum.
The main forces acting on a falling object are gravity and air resistance. Gravity pulls the object downward toward the ground, while air resistance, or drag, slows down its descent by pushing upward against it. The net force of gravity minus air resistance determines the object's overall acceleration as it falls.
the object will floatit shows increasing acceleration
The object opposes the air and while falling of the object the initial velocity will become zero , and the final velocity will have some value's this is how air will resist the velocity of falling object ...........
You're fishing for "air resistance" but your description isn't correct. Air resistance doesn't "slow" a falling object. Once the object has built up to some particular speed of fall, air resistance prevents it from falling any faster.
An example of air friction is when an object moving through the air experiences resistance due to the interaction between its surface and the air molecules. This resistance slows down the object's motion, such as when a skydiver experiences air resistance while falling through the atmosphere.
The two forces acting on a falling object are gravity and air resistance. Gravity pulls the object downward, while air resistance acts in the opposite direction to slow down the object as it falls through the air.