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<p><b>New page</b></p><div>[[File:Drop_time.jpg|Drop time|thumb]] [[File:Free-fall.gif|Free-fall|thumb|left]] [[File:MeteorAccGraph.jpg|MeteorAccGraph|thumb|left]] '''Free fall''' is a physical phenomenon that occurs when an object is subjected to gravitational force only, with no other forces acting upon it. This condition is an idealized scenario that assumes the absence of other forces, such as air resistance. In the context of [[Earth]]'s gravity, free fall occurs when an object falls solely under the influence of [[gravity]], neglecting the effects of air resistance, which in reality slows down the object's fall.<br />
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==Definition==<br />
In [[physics]], free fall is defined as the motion of an object where gravity is the only force acting upon it. The state of free fall occurs when the only force acting on an object is the gravitational force, making the object accelerate at a constant rate known as the acceleration due to gravity (denoted as ''g''). On the surface of the Earth, ''g'' is approximately 9.81 m/s^2, meaning that in the absence of air resistance, an object in free fall will increase its velocity by 9.81 meters per second every second.<br />
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==Conditions for Free Fall==<br />
For an object to be in free fall:<br />
* The object must not be subjected to air resistance or any other form of drag.<br />
* It must be in a vacuum or a medium where such resistive forces are negligible.<br />
* The only force acting on the object is the gravitational force.<br />
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==Equations of Motion==<br />
The motion of an object in free fall can be described by the following equations, assuming the object starts from rest:<br />
* Velocity (''v'') after time (''t''): ''v'' = ''gt''<br />
* Distance (''s'') fallen after time (''t''): ''s'' = ½''gt''^2<br />
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These equations assume that the starting velocity is zero and that the motion is in a straight line in the direction of the gravitational force.<br />
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==Examples of Free Fall==<br />
* An apple falling from a tree, ignoring air resistance.<br />
* An astronaut floating in the [[International Space Station]], where the station and the astronaut inside are both in free fall around the Earth, creating a condition of weightlessness.<br />
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==Misconceptions==<br />
A common misconception is that objects in free fall experience no gravity. In reality, free fall occurs because of the presence of gravity. The sensation of weightlessness or the absence of weight is due to the object being in a state of continuous fall towards the center of the gravitational field, with no support forces acting on it.<br />
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==Historical Perspective==<br />
The concept of free fall has been a subject of fascination and study for centuries. [[Galileo Galilei]] is often credited with the early development of the understanding of free fall. Galileo conducted experiments by dropping objects from the [[Leaning Tower of Pisa]], demonstrating that the acceleration of free fall is the same for objects of different masses, a principle that contradicted the then-prevailing Aristotelian belief that heavier objects fall faster.<br />
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==Applications==<br />
Understanding free fall is crucial in various fields, including [[aerospace engineering]], where it is essential for calculating the orbits of [[satellites]] and planning the trajectories of spacecraft. It also has applications in sports science, amusement park design, and safety testing for vehicles.<br />
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[[Category:Physics]]<br />
[[Category:Mechanics]]<br />
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