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No, momentum = mass x velocity. Since the leaves on the ground are not moving v = 0 which means their momentum is also zero. Since the leaf falling is moving and has a mass, it will have a momentum greater than zero.
Less mass means less momentum. Momentum also depends on the velocity.
Momentum is the product of mass times velocity. With less velocity, there will be less momentum. (An object's mass will usually not change.)
With less inertia.
it takes less energy to maintain momentum than to acheive it.
No, momentum = mass x velocity. Since the leaves on the ground are not moving v = 0 which means their momentum is also zero. Since the leaf falling is moving and has a mass, it will have a momentum greater than zero.
Less mass means less momentum. Momentum also depends on the velocity.
Momentum is the product of mass times velocity. With less velocity, there will be less momentum. (An object's mass will usually not change.)
More momentum would mean that the team has recently won several games or matches, and opposite for less momentum.
If you drop a suitcase out of a moving car, the momentum of the car will decrease as there will be less mass, therefore less momentum. :)
With less inertia.
it takes less energy to maintain momentum than to acheive it.
Less than what? Please clarify.
you would have to be with less momentum better so acceleration isn't required. It would be the flux capacitor. without a doubt.
Momentum is mass x velocity, so it would also depend on each ball's velocity.
If an object has more momentum, it has either a greater mass or a greater velocity. If an object has less inertia, it has less mass. So am object with less inertia will accelerate faster than one with greater momentum because of a greater mass, assuming the same force of acceleration is applied to both. However, if the greater momentum is due to greater velocity, not enough information has been provided to answer the question.
The electron, because it has much less mass than the proton and momentum is the product of mass and speed.