The momentum of an object is given by the formula: momentum = mass x velocity. Therefore, the combined momentum of Spaceship 1 and Spaceship 2 after the collision would be the sum of their individual momentums. Since they have equal masses and are moving in the same direction, you can simply add their individual momentums to get the combined momentum.
The momentum of an object is given by the product of its mass and velocity. Therefore, the momentum of spaceship 1 before the collision is 0 kgm/s and the momentum of spaceship 2 before the collision is 1800 kgm/s. When they collide and stick together, their momenta are added, resulting in a combined momentum of 1800 kg*m/s.
Momentum = (mass) x (velocity), in the same direction as the velocity.Spaceship-1 . . . Momentum = (300) x (2) = 600 kg-m/sec, in some direction.Spaceship-2 . . . Momentum = (300) x (1) = 300 kg-m/sec, in the same direction.Their combined momentum = 900 kg-m/sec, in their common direction.
When two billiard balls collide, the total change in momentum is equal to zero according to the law of conservation of momentum. This means that the combined momentum of the two balls before the collision is equal to the combined momentum after the collision.
Their speed after the collision will be 0 m/s since Spaceship 1 was stationary and Spaceship 2 had no stated speed. The total momentum before the collision is zero, so the total momentum after the collision will also be zero if they stick together.
Momentum is a vector quantity, meaning it has both magnitude and direction. The direction of momentum is the same as the direction of the velocity of an object. This is because momentum is defined as the product of an object's mass and velocity, and velocity has a direction.
The momentum of an object is given by the product of its mass and velocity. Therefore, the momentum of spaceship 1 before the collision is 0 kgm/s and the momentum of spaceship 2 before the collision is 1800 kgm/s. When they collide and stick together, their momenta are added, resulting in a combined momentum of 1800 kg*m/s.
2m/s
Momentum = (mass) x (velocity), in the same direction as the velocity.Spaceship-1 . . . Momentum = (300) x (3) = 900 kg-m/sec, in some direction.Spaceship-2 . . . Momentum = (300) x (2) = 600 kg-m/sec, in the same direction.Their combined momentum = 1,500 kg-m/sec, in their common direction.
900kg-m/s
Momentum is mass multiplied by velocity. The momentum of the two ships would be 300 x 2 = 600 kgm/s and 300 x 1 = 300 kgm/s. So the combined momentum of the two ships would be 900 kgm/s.
Momentum = (mass) x (velocity), in the same direction as the velocity.Spaceship-1 . . . Momentum = (300) x (2) = 600 kg-m/sec, in some direction.Spaceship-2 . . . Momentum = (300) x (1) = 300 kg-m/sec, in the same direction.Their combined momentum = 900 kg-m/sec, in their common direction.
600kg-m/s apex miles
Momentum = (mass) x (velocity), in the same direction as the velocity.Spaceship-1 . . . Momentum = (300) x (2) = 600 kg-m/sec, in some direction.Spaceship-2 . . . Momentum = (300) x (1) = 300 kg-m/sec, in the same direction.Their combined momentum = 900 kg-m/sec, in their common directionbut the answer is 1500 kg-ms
Momentum = (mass) x (velocity), in the same direction as the velocity.Spaceship-1 . . . Momentum = (300) x (3) = 900 kg-m/sec, in some direction.Spaceship-2 . . . Momentum = (300) x (2) = 600 kg-m/sec, in the same direction.Their combined momentum = 1,500 kg-m/sec, in their common direction.Apex- 900 kg-m/s
Momentum = (mass) x (velocity), in the same direction as the velocity.Spaceship-1 . . . Momentum = (150) x (0) = 0 kg-m/sec, in some direction.Spaceship-2 . . . Momentum = (150) x (6) = 900 kg-m/sec, in the same direction.Their combined momentum = 900 kg-m/sec, in their common direction.
1,500 kg-m/s900 kg-m/s apex
When two billiard balls collide, the total change in momentum is equal to zero according to the law of conservation of momentum. This means that the combined momentum of the two balls before the collision is equal to the combined momentum after the collision.