If the objects differ in mass so will the speeds differ after collision. Let's not forget that the net momentum of the both balls should be the same before and after collision. So of the 10 g blue ball travelling at an unknown velocity strikes the stationary 1 g orange ball, the orange ball will surely have to travel at a greater velocity after the collision in order for the net momentum to be the same.

Consider the animation on the right showing an elastic collision between two objects. What is the initial velocity of the blue ball?

Momentum is conserved, so the net momentum before collision equals the net momentum after collision. Since the orange ball is stationary its momentum is 0. The only momentum of the system before collision is due to the moving blue ball. So we can write the expression below.

Mass_{(blue ball)} X velocity_{(blue ball)} = Mass_{(orange ball)} X velocity_{(orange ball)}

=> 0.01 Kg X V_{(blue ball)} = 0.001 Kg X 30 m/s

=> V_{(blue ball)} = (0.001 Kg X 30 m/s) 0.01 Kg

=> V_{(blue ball)} = 3 m/s

Momentum is conserved, so the net momentum before collision equals the net momentum after collision. Since the blue ball is stationary its momentum is 0. The only momentum of the system before collision is due to the moving orange ball. So we can write the expression below.

Mass_{(coupled balls)} X velocity_{(coupled ball)} = Mass_{(orange ball)} X velocity_{(orange ball)}

=> Mass_{(coupled balls)} X 1 m/s = 6Kg X 2m/s

=> Mass_{(coupled balls)}= (6Kg X 2m/s) / 1 m/s

=> Mass_{(coupled balls)}= 12 Kg

=> so the blue ball also has a mass of 6 Kg.