(a) 138.2 J
Since the applied force is parallel to the displacement of the block, the work done by the force is given by:
[tex]W=Fd[/tex]
where
F = 46.7 N is the magnitude of the force
d = 2.96 m is the displacement of the block
Substituting the numbers into the equation, we find
[tex]W=(46.7 N)(2.96 m)=138.2 J[/tex]
(b) 45.1 J
In order to calculate the total energy dissipated among the floor and the block as thermal energy, we have to calculate the work done by the frictional force, which is
[tex]W_f = F_f d = (-\mu mg)d[/tex]
where[tex]\mu=0.635[/tex] is the coefficient of friction
m = 4.35 kg is the mass of the block
g = 9.8 m/s^2
d = 2.96 m is the displacement
and the negative sign is due to the fact that the frictional force has opposite direction to the displacement.
Substituting, we find
[tex]W_f =-(0.635)(4.35 kg)(9.8 m/s^2)(2.96 m)=-80.1 J[/tex]
The magnitude of this work is equal to the sum of the thermal energy dissipated between the floor and the block:
[tex]W_f = E_{floor}+E_{block}[/tex]
And since we know
[tex]W_f = 80.1 J\\E_{floor}=35.0 J[/tex]
we find
[tex]E_{floor}=W_f-E_{block}=80.1 J-35.0 J=45.1 J[/tex]
(c) 58.1 J
According to the work-energy theorem, the increase in kinetic energy of the block must be equal to the work done by the applied force minus the work done by friction (which becomes wasted thermal energy):
[tex]\Delta K=W-W_f[/tex]
Substituting
[tex]W=138.2 J\\W_f = 80.1 J[/tex]
We find
[tex]\Delta K=138.2 J-80.1 J=58.1 J[/tex]
