Respuesta :
Answer:
velocity = 62.89 m/s in 58 degree measured from the x-axis
Explanation:
Relevant information:
Before the collision, asteroid A of mass 1,000 kg moved at 100 m/s, and asteroid B of mass 2,000 kg moved at 80 m/s.
Two asteroids moving with velocities collide at right angles and stick together. Asteroid A initially moving to right direction and asteroid B initially move in the upward direction.
Before collision Momentum of A = 1000 x 100 = [tex]$ 10^5$[/tex] kg - m/s in the right direction.
Before collision Momentum of B = 2000 x 80 = 1.6 x [tex]$ 10^5$[/tex] kg - m/s in upward direction.
Mass of System of after collision = 1000 + 2000 = 3000 kg
Now applying the Momentum Conservation, we get
Initial momentum in right direction = final momentum in right direction = [tex]$ 10^5$[/tex]
And, Initial momentum in upward direction = Final momentum in upward direction = 1.6 x [tex]$ 10^5$[/tex]
So, [tex]$ V_x = \frac{10^5}{3000} $[/tex] = [tex]$ \frac{100}{3} $[/tex] m/s
and [tex]$ V_y=\frac{160}{3}$[/tex] m/s
Therefore, velocity is = [tex]$ \sqrt{V_x^2 + V_y^2} $[/tex]
= [tex]$ \sqrt{(\frac{100}{3})^2 + (\frac{160}{3})^2} $[/tex]
= 62.89 m/s
And direction is
tan θ = [tex]$ \frac{V_y}{V_x}$[/tex] = 1.6
therefore, [tex]$ \theta = \tan^{-1}1.6 $[/tex]
= [tex]$ 58 ^{\circ}$[/tex] from x-axis
