Answer:
[tex]K=512J[/tex]
Explanation:
Since the surface is frictionless, momentum will be conserved. If the bullet of mass [tex]m_1[/tex] has an initial velocity [tex]v_{1i}[/tex] and a final velocity [tex]v_{1f}[/tex] and the block of mass [tex]m_2[/tex] has an initial velocity [tex]v_{2i}[/tex] and a final velocity [tex]v_{2f}[/tex] then the initial and final momentum of the system will be:
[tex]p_i=m_1v_{1i}+m_2v_{2i}[/tex]
[tex]p_f=m_1v_{1f}+m_2v_{2f}[/tex]
Since momentum is conserved, [tex]p_i=p_f[/tex], which means:
[tex]m_1v_{1i}+m_2v_{2i}=m_1v_{1f}+m_2v_{2f}[/tex]
We know that the block is brought to rest by the collision, which means [tex]v_{2f}=0m/s[/tex] and leaves us with:
[tex]m_1v_{1i}+m_2v_{2i}=m_1v_{1f}[/tex]
which is the same as:
[tex]v_{1f}=\frac{m_1v_{1i}+m_2v_{2i}}{m_1}[/tex]
Considering the direction the bullet moves initially as the positive one, and writing in S.I., this gives us:
[tex]v_{1f}=\frac{(0.01kg)(2000m/s)+(4kg)(-4.2m/s)}{0.01kg}=320m/s[/tex]
So kinetic energy of the bullet as it emerges from the block will be:
[tex]K=\frac{mv^2}{2}=\frac{(0.01kg)(320m/s)^2}{2}=512J[/tex]
