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Yes. Force= mass times acceleration if mass is large the force is large.
Mass doesn't affect air resistance directly. Air resistance is affected by the shape of the object. However, other things (shape, density) being equal, an object with a greater mass will have greater air resistance, simply because it is bigger. On the other hand, the larger object will have a smaller ratio of air resistance to mass, since mass will increase with the third power of the diameter (or any linear measurement), while the surface area - which affects air resistance - will only be proportional to the second power of the diameter. This will make a larger object fall faster.
the object has less mass. the object has a large surface.
When an object falls through air, it experiences air resistance. This air resistance is a force that opposes the object's motion. The amount of air resistance an object experiences depends on the object's shape, size, and speed. A man using a parachute falls slowly because the parachute creates a large amount of air resistance. A stone falls very fast because it has a small amount of air resistance.
When an object is falling, its motion is most affected by air resistance when it has a large surface area and is moving at high speeds. This is because air resistance is directly proportional to the surface area of the object and the square of its velocity. Therefore, larger objects or those moving faster experience greater air resistance, which can significantly affect their motion.
Yes. Force= mass times acceleration if mass is large the force is large.
Mass doesn't affect air resistance directly. Air resistance is affected by the shape of the object. However, other things (shape, density) being equal, an object with a greater mass will have greater air resistance, simply because it is bigger. On the other hand, the larger object will have a smaller ratio of air resistance to mass, since mass will increase with the third power of the diameter (or any linear measurement), while the surface area - which affects air resistance - will only be proportional to the second power of the diameter. This will make a larger object fall faster.
the object has less mass. the object has a large surface.
The small ball will feel the most force. The speed and weight of the car creates a bigger force because there is more energy coming from the car.
When an object falls through air, it experiences air resistance. This air resistance is a force that opposes the object's motion. The amount of air resistance an object experiences depends on the object's shape, size, and speed. A man using a parachute falls slowly because the parachute creates a large amount of air resistance. A stone falls very fast because it has a small amount of air resistance.
When an object is falling, its motion is most affected by air resistance when it has a large surface area and is moving at high speeds. This is because air resistance is directly proportional to the surface area of the object and the square of its velocity. Therefore, larger objects or those moving faster experience greater air resistance, which can significantly affect their motion.
Inertia. The larger the mass of the body the larger its inertia, in other words a heavy object would require a large driving force to make it initially move and a large force as well to make it stop moving or change direction.
Inertia. The larger the mass of the body the larger its inertia, in other words a heavy object would require a large driving force to make it initially move and a large force as well to make it stop moving or change direction.
It is important to note that a large force exerted over a short period of time can give the same impulse as a small force exerted over a long period of time.
It will stay at rest.
It will stay at rest.
When you apply a force to a mass you produce acceleration. "Tiny" and "large" are not well defined here, but the basic equation is F = ma, so if the forces are proportional to the masses in each case (for example, a 0.1 N force applied to a 0.1 g object and a 1000 N force applied to a 1000 g object) then you will produce the same acceleration for both objects.