When a ball hits a wall, the force of the ball hitting the wall (impact force) pushes against the wall, while the wall exerts an equal and opposite force back on the ball (reaction force).
i think its compression and ... sorry i don't know the other one
The equal action and reaction forces do not cancel each other out when one person hits a ball because they act on different objects. The force exerted by the person hitting the ball causes the ball to accelerate in the direction of the force, while the reaction force from the ball pushes back on the person, causing them to feel the impact of hitting the ball.
When you throw a ball, two main forces act on it: the force of the throw propelling it forward, and the force of gravity pulling it downward. The throw provides the initial thrust while gravity causes the ball to follow a curved path back to the ground.
When two forces act on a rubber ball, they can change its shape and size. The forces can compress or stretch the ball, affecting its elasticity and rebound characteristics. Additionally, the forces can also cause the ball to accelerate or decelerate depending on their direction and magnitude.
When a ball is dropped, the main forces acting on it are gravity and air resistance. Gravity pulls the ball downwards towards the Earth, while air resistance pushes against the ball as it falls, causing drag. These forces determine the speed and trajectory of the ball as it descends.
i think its compression and ... sorry i don't know the other one
The equal action and reaction forces do not cancel each other out when one person hits a ball because they act on different objects. The force exerted by the person hitting the ball causes the ball to accelerate in the direction of the force, while the reaction force from the ball pushes back on the person, causing them to feel the impact of hitting the ball.
The action and reaction forces act on different objects. For two forces to cancel each other - and provide a net force of zero, for Newton's First Law - they must act on the same object.
When you throw a ball, two main forces act on it: the force of the throw propelling it forward, and the force of gravity pulling it downward. The throw provides the initial thrust while gravity causes the ball to follow a curved path back to the ground.
When two forces act on a rubber ball, they can change its shape and size. The forces can compress or stretch the ball, affecting its elasticity and rebound characteristics. Additionally, the forces can also cause the ball to accelerate or decelerate depending on their direction and magnitude.
BECAUSE THE FORCES AREN'T EQUAL IF THEY WERE THE BALL WOULD FALL STRAIT DOWN. the bat (even if it were lighter than the ball) has more inertia/energy which cancels out the kinetic energy of the ball, the residual kinectic energy of the bat that isn't canceled out changes the direction of the ball, the more direct the angle the more effective and further the ball will go
Kinetic energy, momentum, gravity.
When a ball is dropped, the main forces acting on it are gravity and air resistance. Gravity pulls the ball downwards towards the Earth, while air resistance pushes against the ball as it falls, causing drag. These forces determine the speed and trajectory of the ball as it descends.
The force of gravity, weight = mg.
When a tennis ball rolls on grass, three main forces act on it: gravitational force pulling it downward, normal force exerted by the grass to support the ball's weight, and rolling resistance caused by friction between the ball and the grass.
The main forces acting on a ball sinking in water are gravity, buoyancy, and drag. Gravity pulls the ball downward, buoyancy pushes the ball upward due to water displacement, and drag resists the ball's motion through the water, slowing it down.
The four forces acting on the ball when it is pushed are: The force of your hand pushing the ball forward. The force of friction between the ball and the table resisting its motion. The force of gravity pulling the ball downward. The normal force exerted by the table on the ball to support its weight.