In the absence of air resistance, mass does not affect the motion of a projectile. All objects fall at the same rate regardless of their mass in a vacuum. This principle is described by Galileo's law of falling bodies.
True. Objects falling through the air experience air resistance, which is a type of friction that opposes the motion of the object.
Yes, falling objects experience air resistance. As an object falls through the air, it pushes air molecules out of the way, resulting in a force opposite to the object's motion. This air resistance depends on the object's size, shape, and speed.
A. True. Objects falling through the air experience air resistance, which is a type of friction that opposes the motion of the object.
The hypothesis is that air resistance decreases the velocity of falling objects. As an object falls, the force of air resistance acting against the object's motion increases, ultimately slowing down the object and reducing its velocity compared to in a vacuum.
In the absence of air resistance, mass does not affect the motion of a projectile. All objects fall at the same rate regardless of their mass in a vacuum. This principle is described by Galileo's law of falling bodies.
True. Objects falling through the air experience air resistance, which is a type of friction that opposes the motion of the object.
Yes, falling objects experience air resistance. As an object falls through the air, it pushes air molecules out of the way, resulting in a force opposite to the object's motion. This air resistance depends on the object's size, shape, and speed.
A. True. Objects falling through the air experience air resistance, which is a type of friction that opposes the motion of the object.
The hypothesis is that air resistance decreases the velocity of falling objects. As an object falls, the force of air resistance acting against the object's motion increases, ultimately slowing down the object and reducing its velocity compared to in a vacuum.
The type of friction that objects falling through air experience is called air resistance or drag. This friction force opposes the motion of the falling object, ultimately affecting its speed and trajectory.
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.
Without air resistance, falling objects would accelerate at a constant rate due to gravity. This means that they would fall faster and reach the ground in a shorter amount of time compared to falling with air resistance. The absence of air resistance would also remove any upward force opposing the motion of the falling object.
All objects, under these conditions, will accelerate at the same rate as they fall. (Note: Just the fact that you can call it a "falling" object is one of the effects of gravity.)
Two forces that affect nearly all motion are gravity, which pulls objects towards the Earth's center, and friction, which opposes the motion of objects moving against a surface.
The mass of an object will not affect the time it takes for it to reach the ground from a fixed height. Backspace
These are all examples of forces that act on objects and affect their motion. Gravity is the force that pulls objects towards each other, friction opposes the motion of objects sliding against each other, and air resistance slows down the motion of objects moving through the air.