Answer: Third option
F = 250w
Explanation:
The impulse can be written as the product of force for the time interval in which it is applied.
[tex]I = F (t_2-t_1)[/tex]
You can also write impulse I as the change of the linear momentum of the ball
[tex]I = mv_2 -mv_1[/tex]
So:
[tex]F (t_2-t_1) = mv_2 -mv_1[/tex]
We want to find the force applied to the ball. We know that
[tex](t_2-t_1) = 30[/tex] milliseconds = 0.03 seconds
The initial velocity [tex]v_1[/tex] is zero.
The final speed [tex]v_2 = 73.14\ m / s[/tex]
So
[tex]F * 0.03 = 73.14m[/tex]
[tex]F * 0.03 = 73.14m\\\\F=\frac{73.14m}{0.03}\\\\F=2438m[/tex]
We must express the result of the force in terms of the weight of the ball.
We divide the expression between the acceleration of gravity
[tex]g = 9.8\ m / s ^ 2[/tex]
[tex]F=\frac{2438m*g}{g},\ \ m*g=w\\\\g=9.8\ m/s^2\\\\F=\frac{2438w}{9.8}\\\\F=249w[/tex]
The answer is the third option
