Answer:
The final speed for the mass 2m is [tex]v_{2y}=-1,51\ v_{i}[/tex] and the final speed for the mass 9m is [tex]v_{1f} =0,85\ v_{i}[/tex].
The angle at which the particle 9m is scattered is [tex]\theta = -66,68^{o}[/tex] with respect to the - y axis.
Explanation:
In an elastic collision the total linear momentum and the total kinetic energy is conserved.
Conservation of linear momentum:
Because the linear momentum is a vector quantity we consider the conservation of the components of momentum in the x and y axis.
The subindex 1 will refer to the particle 9m and the subindex 2 will refer to the particle 2m
[tex]\vec{p}=m\vec{v}[/tex]
[tex]p_{xi} =p_{xf}[/tex]
In the x axis before the collision we have
[tex]p_{xi}=9m\ v_{i} - 2m\ v_{i}[/tex]
and after the collision we have that
[tex]p_{xf} =9m\ v_{1x}[/tex]
In the y axis before the collision [tex]p_{yi} =0[/tex]
after the collision we have that
[tex]p_{yf} =9m\ v_{1y} - 2m\ v_{2y}[/tex]
so
[tex]p_{xi} =p_{xf} \\7m\ v_{i} =9m\ v_{1x}\Rightarrow v_{1x} =\frac{7}{9}\ v_{i}[/tex]
then
[tex]p_{yi} =p_{yf} \\0=9m\ v_{1y} -2m\ v_{2y} \\v_{1y}=\frac{2}{9} \ v_{2y}[/tex]
Conservation of kinetic energy:
[tex]\frac{1}{2}\ 9m\ v_{i} ^{2} +\frac{1}{2}\ 2m\ v_{i} ^{2}=\frac{1}{2}\ 9m\ v_{1f} ^{2} +\frac{1}{2}\ 2m\ v_{2f} ^{2}[/tex]
so
[tex]\frac{11}{2}\ m\ v_{i} ^{2} =\frac{1}{2} \ 9m\ [(\frac{7}{9}) ^{2}\ v_{i} ^{2}+ (\frac{2}{9}) ^{2}\ v_{2y} ^{2}]+ m\ v_{2y} ^{2}[/tex]
Putting in one side of the equation each speed we get
[tex]\frac{25}{9}\ m\ v_{i} ^{2} =\frac{11}{9}\ m\ v_{2y} ^{2}\\v_{2y} =-1,51\ v_{i}[/tex]
We know that the particle 2m travels in the -y axis because it was stated in the question.
Now we can get the y component of the speed of the 9m particle:
[tex]v_{1y} =\frac{2}{9}\ v_{2y} \\v_{1y} =-0,335\ v_{i}[/tex]
the magnitude of the final speed of the particle 9m is
[tex]v_{1f} =\sqrt{v_{1x} ^{2}+v_{1y} ^{2} }[/tex]
[tex]v_{1f} =\sqrt{(\frac{7}{9}) ^{2}\ v_{i} ^{2}+(-0,335)^{2}\ v_{i} ^{2} }\Rightarrow \ v_{1f} =0,85\ v_{i}[/tex]
The tangent that the speed of the particle 9m makes with the -y axis is
[tex]tan(\theta)=\frac{v_{1x} }{v_{1y}} =-2,321 \Rightarrow\theta=-66,68^{o}[/tex]
As a vector the speed of the particle 9m is:
[tex]\vec{v_{1f} }=\frac{7}{9} v_{i} \hat{x}-0,335\ v_{i}\ \hat{y}[/tex]
As a vector the speed of the particle 2m is:
[tex]\vec{v_{2f} }=-1,51\ v_{i}\ \hat{y}[/tex]
