YES
Yes, objects falling in free fall have a constant acceleration due to gravity.
The acceleration due to gravity is constant for a freely falling body. This means that the object will experience a constant acceleration of 9.81 m/s^2 (on Earth) in the downward direction, regardless of its mass. This allows us to predict the motion of the object using equations of motion.
No, changing the mass of a free-falling body does not affect the value of the acceleration due to gravity. The acceleration due to gravity is a constant value that is independent of the mass of the object. All objects fall at the same rate in a vacuum due to gravity.
there arent any.
A - 9.8m/s2
The acceleration due to gravity (free fall acceleration) is approximately 9.81 m/s^2 near the Earth's surface. Within a few hundred miles on Earth's surface, the gravitational force remains relatively constant, so the acceleration experienced by falling objects remains constant. This allows us to treat free fall acceleration as a constant in practical situations.
To study the acceleration of a free-falling body, you could modify the experiment by using a motion sensor to measure the position of the falling object at different time intervals. By collecting data on the position of the object over time, you can calculate the acceleration using the formula a = 2*(d/t^2), where a is acceleration, d is distance fallen, and t is time elapsed. This data can help you analyze the acceleration of the free-falling body accurately.
False
The value of acceleration in a free-falling body is constant (g). The mass of the body will have no effect on the acceleration. On earth, if you drop a heavy weight and a feather together, the weight will hit the ground first because the feather is held back by air resistance. If you do the same thing in a vacuum (as was demonstrated by an astronaut on the moon) both will hit the ground at the same time.
depends on where it falls - on mars, earth or sun... On earth, it is about 9,8 m/sec^2. In general, it can be estimated by newton's formula F=G*m*M/R^2, where G is a constant, m is mass of the falling body, M is a mass of gravitating object (earth) R is distance between them. Consequently, acceleration is F/m = ...
The acceleration of a falling body due to gravity is approximately 9.81 m/s^2, often rounded to 10 m/s^2 for simplicity. This means that the speed of a falling body increases by 9.81 meters per second every second.
At terminal velocity, the acceleration of a falling object is zero. Terminal velocity is the constant speed that a freely falling object eventually reaches when the resistance of the medium (such as air) through which it is falling equals the force of gravity.