Answer:
1) 1.31 m/s2
2) 20.92 N
3) 8.53 m/s2
4) 1.76 m/s2
5) -8.53 m/s2
Explanation:
1) As the box does not slide, the acceleration of the box (relative to ground) is the same as acceleration of the truck, which goes from 0 to 17m/s in 13 s
[tex]a = \frac{\Delta v}{\Delta t} = \frac{17 - 0}{13} = 1.31 m/s2[/tex]
2)According to Newton 2nd law, the static frictional force that acting on the box (so it goes along with the truck), is the product of its mass and acceleration
[tex]F_s = am = 1.31*16 = 20.92 N[/tex]
3) Let g = 9.81 m/s2. The maximum static friction that can hold the box is the product of its static coefficient and the normal force.
[tex]F_{\mu_s} = \mu_sN = mg\mu_s = 16*9.81*0.87 = 136.6N[/tex]
So the maximum acceleration on the block is
[tex]a_{max} = F_{\mu_s} / m = 136.6 / 16 = 8.53 m/s^2[/tex]
4)As the box slides, it is now subjected to kinetic friction, which is
[tex]F_{\mu_s} = mg\mu_k = 16*9.81*0.69 = 108.3 N[/tex]
So if the acceleration of the truck it at the point where the box starts to slide, the force that acting on it must be at 136.6 N too. So the horizontal net force would be 136.6 - 108.3 = 28.25N. And the acceleration is
28.25 / 16 = 1.76 m/s2
5) Same as number 3), the maximum deceleration the truck can have without the box sliding is -8.53 m/s2
