Resistance, or drag, acts opposite to the direction of motion and reduces the acceleration of aircraft. High resistance can slow down an aircraft and make it harder to increase speed or maintain acceleration. Pilots account for resistance when planning maneuvers and adjusting engine power to overcome drag.
Mass measures the body's resistance to acceleration.
Acceleration would increase the most when a force is applied in the direction of motion and there is little resistance or friction opposing the motion. This means that the object can gain speed more quickly as the force has a greater effect on its acceleration.
Mass acceleration and air resistance are related by Newton's second law of motion. As an object accelerates, air resistance acts in the opposite direction, slowing down the object. The greater the air resistance, the more it counteracts the acceleration of the object.
The acceleration of a rocket depends on the thrust produced by the engine and the mass of the rocket. A higher thrust will result in greater acceleration, while a higher mass will decrease acceleration. Air resistance can also affect acceleration, with lower air resistance allowing for greater acceleration.
Surface area typically has a minimal effect on acceleration. Acceleration is primarily influenced by factors like force, mass, and friction. In situations where surface area might have an impact, such as in fluid resistance, a larger surface area could create more drag and result in slightly slower acceleration.
Resistance, primarily in the form of drag, opposes the forward motion of an aircraft, thereby reducing its acceleration. As drag increases with speed, it requires more thrust from the engines to overcome this resistance, which can limit the aircraft's ability to accelerate efficiently. Consequently, higher resistance can lead to longer takeoff distances and reduced climb rates. In essence, greater resistance diminishes the net force acting on the aircraft, resulting in lower acceleration.
Well, the more the air resistance, the lower the acceleration.
Mass measures the body's resistance to acceleration.
Acceleration would increase the most when a force is applied in the direction of motion and there is little resistance or friction opposing the motion. This means that the object can gain speed more quickly as the force has a greater effect on its acceleration.
The change in velocity, in this case, is equal to acceleration x time.
It reduces the acceleration of the falling object due to friction.
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.
It depends on the aircraft.
perfectly constant acceleration? Hypothetically, virtually infinite speed? A few things
Mass acceleration and air resistance are related by Newton's second law of motion. As an object accelerates, air resistance acts in the opposite direction, slowing down the object. The greater the air resistance, the more it counteracts the acceleration of the object.
Acceleration does not effect gravity. It is rather the other way round. Gravity can affect the rate of acceleration.
The acceleration of a rocket depends on the thrust produced by the engine and the mass of the rocket. A higher thrust will result in greater acceleration, while a higher mass will decrease acceleration. Air resistance can also affect acceleration, with lower air resistance allowing for greater acceleration.