Answer:
The spring was initially compressed an distance: [tex]x=\sqrt{\frac{7mgR}{k} }[/tex].
Explanation:
We need to apply the conservation of energy law to find the kinetic energy at the top of the loop. First we need to find the initial state as: [tex]E_{1}=E_{k1} +E_{U1} =\frac{kx^{2} }{2}[/tex] where E1 is the mechanical energy at the state 1, Ek1 is the initial kinetic energy that in this case is Ek1=0 and Eu1 is the spring's potential energy and is Eu1=(1/2)kx^2. Then We need to find the final state as:[tex]E_{2}=E_{k2}+E_{U2}=\frac{mv_{top} ^{2} }{2}+2mgR[/tex]. Remember that the surface is frictionless so [tex]E_{1}=E_{2}[/tex], mechanical energy is conserved. Finally we can replace and getting: [tex]2mgR+\frac{mv_{top} ^{2} }{2}=\frac{kx^{2} }{2}[/tex]. On other side we need to apply Newton's Second Law and using the free body diagram (see attached) of the block at the top of the loop we get:[tex]F=m*a=-mg-N=-\frac{mv_{top} ^{2} }{R}[/tex]. In this problem the force of the loop on the block is equal to twice the magnitude gravitational force on the block so N=2mg. Now solving this we can get:[tex]3mg=\frac{mv_{top} ^{2} }{R}[/tex] and replacing this we will find:[tex]2mgR+\frac{3mgR}{2} =\frac{kx^{2} }{2}[/tex] and solving for x, we can find the spring compressed distance like: [tex]\frac{7mgR}{2} =\frac{kx^{2} }{2}[/tex] so:[tex]x=\sqrt{\frac{7mgR}{k} }[/tex]
