Wedge, assuming the narrow angle is pointed into the wind.
When air resistance is a factor, the ball will return to its original point with less kinetic energy due to the work done against the resistance of the air. The air resistance converts some of the ball's kinetic energy into thermal energy, causing a reduction in the ball's speed.
Less air therefore less air resistance. All other variables being the same, the air at higher elevations is less dense, and therefore provides less resistance to the ball flying through it. This allows the ball to travel further with the same force being applied.
As temperature increases, air density decreases, resulting in less air resistance on the ball as it falls. This reduced air resistance allows the ball to travel slightly higher before gravity pulls it back down. Conversely, in colder temperatures, higher air density increases air resistance, causing the ball to reach a slightly lower height when dropped.
A larger ball will experience greater air resistance when dropped because it has a greater surface area interacting with the air. Air resistance is proportional to the surface area of an object, so the larger ball will slow down faster than a smaller ball when dropped.
Slower than the initial speed it was thrown upward with due to air resistance causing the ball to lose speed as it travels through the air. The force of air resistance acts against the direction of motion and slows down the ball.
A crumpled paper ball has a smaller surface area compared to a flat sheet of paper, which increases air resistance and slows down its fall. The crumpled ball also has more internal air resistance, which further hinders its fall speed.
Yes, in hot air the air is a lot thinner so there is less resistance compared to cold air which is a lot denser so more resistance.
The amount of air affects the distance it travels because more air provides greater resistance to movement. This resistance can slow down the object (like a ball or projectile) and reduce the distance it can travel. Conversely, less air will result in less resistance, allowing the object to travel farther.
The mass of the objects don't matter in free fall - they both fall at the same time, assuming air resistance is negligible. However in your case, the golf ball has less air resistance than a tennis ball (add that to the fact tennis ball consist most of air inside adding more to the air resistance). Therefore, the golf ball falls faster than a tennis ball - Hope that helped!
Two things affect the balls while falling - Gravity and Air Resistance. Gravity affects both balls equally. Air resistance exerts a similar force on objects of the same size and shape. A Foam ball weighs less so the same amount of air resistance causes a larger slowing effect on a light foam ball than it does on a heavy rubber ball.
Yes, stadiums with higher altitude can make the ball travel farther because the air is less dense at higher altitudes. This means there is less air resistance, allowing the ball to travel through the air more easily and potentially go higher.
Small objects have less air resistance because they have less surface area compared to larger objects. Air resistance is caused by the interaction between the object's surface and air molecules as they flow around it. With less surface area, there are fewer interactions and therefore less air resistance acting on the object.