x = 1/2 g t2 = (4.9) (10)2 = 490 meters
Yes, an object freely falling still has mass. Mass is a measure of the amount of matter in an object, and it remains constant regardless of the object's motion. The force of gravity acting on the object is what causes it to fall.
122.5 meters (402.5 feet)
when the acceleration of the freely falling object is equal to the acceleration due to gravity then there occurs free fall.
Assuming the object is falling under gravity, it will fall approximately 78.4 meters in 4 seconds. This is based on the formula: distance = 0.5 x acceleration due to gravity x time squared.
Let's imagine there is no air resistance and that gravity is the only thing affecting a falling object. Such an object would then be in free fall. Freely falling objects are affected only by gravity
Gravity is forcing an object to fall to the ground. Another force is friction from air pressure on the falling object.
You can increase the time of descent of a freely falling body by increasing its initial height from which it falls. This will give it more distance to cover before reaching the ground, thereby increasing the time it takes to fall. Additionally, you can increase air resistance by changing the shape or size of the falling object, which will also increase the time of descent.
An object falling freely under gravity is known as a free-falling object, where gravity is the only force acting on it. In the absence of other forces like air resistance, the object accelerates at a constant rate of 9.8 m/s^2 (approximately) towards the Earth's surface.
A freely falling projectile is an object that is only acted upon by gravity, moving through the air in a parabolic path while falling towards the ground. It does not have any initial horizontal force or acceleration other than gravity acting upon it.
Before you test it, you could state the hypothesis in two different ways You could say: "The mass of a falling object has no effect on the time it takes to fall some distance." Or you could say: "The time a falling object takes to fall some distance depends on its mass." You could use the same tests to investigate EITHER hypothesis. --------------------------- The mass of a falling object has no effect on the time it takes to fall some distance assuming zero air resistance.
No, distance does not affect the speed of a falling object. In a vacuum, all objects fall at the same rate regardless of their distance from the ground, known as the gravitational acceleration of 9.8 m/s^2.
A falling object.