 # Can Two Objects With Different Masses Have The Same Momentum?

## Is it possible for two objects with the same mass?

Besides being in different gravitational fields, both objects could have the same mass, but at the same time could have a different density.

If an object is more dense, it can pack more molecules with less space.

If an object has less density, it can’t pack as many molecules..

## Does Momentum have direction?

Momentum is a derived quantity, calculated by multiplying the mass, m (a scalar quantity), times velocity, v (a vector quantity). This means that the momentum has a direction and that direction is always the same direction as the velocity of an object’s motion.

## What is momentum in real life?

Momentum in a simple way is a quantity of motion. … If an object does not move then it has no momentum. However, in everyday life it has an importance but many people didn’t recognize it. Momentum is just about every activity that involves motion. It is an essential concept of physics.

## How is it possible for an object with a large mass to have the same momentum as an object with a small mass?

Same momentum means that the large mass must have a small velocity (so that their product is equal to the small mass times a large velocity). … Since they have the same momentum, the object with the larger velocity has a larger kinetic energy – that’s the object with the small mass.

## Is momentum the same as inertia?

Inertia is the resistance offered by a body to the motion whereas momentum is the tendency of a body to continue moving.

## Why do objects with more mass not always have more momentum?

Its mass, for one thing. After all, mass measures the inertia of an object – how much the object resists accelerating. Certainly, more mass means more momentum – the momentum of an object is directly proportional to its mass. Twice the mass means twice the momentum.

## How can two objects have the same momentum but different velocities?

p = mv, where m is the mass and v is the speed. So, if two objects have the same momentum but different speeds, the must have different masses as well. So, the example is correct. Hope this helps!

## Is it true that direction does not matter when you are measuring momentum?

Momentum is not equal to the mass of an object divided by its velocity. … Objects with different masses can’t have the same momentum. False. Direction does not matter when you are measuring momentum.

## Is momentum always conserved?

Collisions. In collisions between two isolated objects Newton’s third law implies that momentum is always conserved. … In collisions between two isolated objects momentum is always conserved. Kinetic energy is only conserved in elastic collisions.

## What happens when you double the mass?

If the net force on an object is doubled, its acceleration will double If the mass of an object is doubled, the acceleration will be halved . … Acceleration will be unchanged because although the mass is doubled, which will cut the acceleration in half, the fore is also doubled which will double the acceleration.

## What is the momentum of a 3 kg bowling ball moving at 3 m s?

In short, Your Answer would be 9 Kg-m/s Hope this helps!

## Will two objects with the same mass always have the same momentum?

Momentum is not equal to the mass of an object divided by its velocity. … Two objects with the same mass will always have the same momentum.

## Can a lighter object have more momentum than a heavier one how?

Question: Can A Lighter Object Have More Momentum Than A Heavier One? … No, Because Momentum Is Independent Of The Mass Of The Object.

## What is the relationship between mass and momentum?

Mass and velocity are both directly proportional to the momentum. If you increase either mass or velocity, the momentum of the object increases proportionally. If you double the mass or velocity you double the momentum.

## What happens when two objects with the same momentum collide?

For a collision occurring between object 1 and object 2 in an isolated system, the total momentum of the two objects before the collision is equal to the total momentum of the two objects after the collision. That is, the momentum lost by object 1 is equal to the momentum gained by object 2.