The force that causes a soccer ball to take a curved path when it is kicked is called the Magnus effect. This effect occurs when the ball spins as it moves through the air, creating differences in air pressure around the ball that result in a curved trajectory.
A thrown object follows a curved path due to the combination of its initial velocity and the force of gravity acting on it. The horizontal velocity propels the object forward, while the vertical force of gravity causes it to accelerate downward, resulting in a curved trajectory. This combination of horizontal and vertical motion gives rise to a curved path.
Curved motion is typically caused by the presence of a force that is not aligned with the direction of motion. This force can be due to factors such as gravity, electromagnetic forces, or friction. The object experiencing the curved motion will deviate from a straight path and follow a curved trajectory as a result of the applied force.
When a soccer ball is kicked, the forces acting on it are initially unbalanced. The force applied by the player's foot creates an unbalanced force, causing the ball to accelerate. As the ball moves through the air, air resistance and gravity act as external forces, creating a balanced force system that eventually slows down and stops the ball's motion. This can be determined by analyzing the net force acting on the ball at any given moment, which is the sum of all external forces.
The force that causes an object, like a ball, to move in a curved path is centripetal force. This force acts towards the center of the curve and is necessary to keep the object moving in a circular motion. Without centripetal force, the object would continue in a straight line tangential to the curve.
The possible speed of a kicked soccer ball varies directly with the force applied over a certain area of the soccer ball, but average speeds are between 20 and 60 miles per hour, while the highest would be upwards of 90 and 100 miles per hour.
The force pulling objects back towards the Earth is gravity.
the soccer ball will move because a force has acted on it.
A thrown object follows a curved path due to the combination of its initial velocity and the force of gravity acting on it. The horizontal velocity propels the object forward, while the vertical force of gravity causes it to accelerate downward, resulting in a curved trajectory. This combination of horizontal and vertical motion gives rise to a curved path.
Curved motion is typically caused by the presence of a force that is not aligned with the direction of motion. This force can be due to factors such as gravity, electromagnetic forces, or friction. The object experiencing the curved motion will deviate from a straight path and follow a curved trajectory as a result of the applied force.
the action force is your foot when u strike the ball the reaction force is the ball being kicked
the action force is your foot when u strike the ball the reaction force is the ball being kicked
Coriolis force
The object at rest will remain at rest unless there is an outside force applied. Example: There is a basketball on the floor. Suddenly, a soccer player kicked it. Explanation: While the basketball is on the floor, it applies force, that is why it is stable--not moving. Then when the soccer player kicked the ball, that is the time that an outside force was applied.
The force that causes an object, like a ball, to move in a curved path is centripetal force. This force acts towards the center of the curve and is necessary to keep the object moving in a circular motion. Without centripetal force, the object would continue in a straight line tangential to the curve.
When a soccer ball is kicked, the forces acting on it are initially unbalanced. The force applied by the player's foot creates an unbalanced force, causing the ball to accelerate. As the ball moves through the air, air resistance and gravity act as external forces, creating a balanced force system that eventually slows down and stops the ball's motion. This can be determined by analyzing the net force acting on the ball at any given moment, which is the sum of all external forces.
Coriolis force
The possible speed of a kicked soccer ball varies directly with the force applied over a certain area of the soccer ball, but average speeds are between 20 and 60 miles per hour, while the highest would be upwards of 90 and 100 miles per hour.