Momentum = mass * velocity. If both cars have the same mass, then the faster one will have more momentum. Probably the slow car doesn't weigh 5 times as much as the fast one, so the fast one most likely has more momentum.
The formula is...momentum=velocity x massSo...momentum= 4m/s x 100kgmomentum= 400 kg m/s
First of all, a football player who's moving at 7 miles per second has more to worryabout than his momentum. That's 25,200 miles an hour, and if somebody doesn'tgrab him, and his helmet doesn't burst into flame from the atmospheric friction,he's going to leave the end-zone and go into low-earth orbit.But we'll just do the math.Momentum = (mass) x (speed)which is easy enough, but we have to make sure that all the units are in the samesystem. Right now they're not, so we have to remember to convert that "7 miles"into meters.Momentum = (100 kg) x (7 mi/sec) x (1,609.344 meter/mile) = 1,126,540.8 kg-m/secThat's roughly the same momentum as a 28-ton truck moving at 100 mph.
The speed after 100 seconds is: speed =1000m/s + 4m/s^2x100s= 1000m/s + 400m/s=1400 m/s.
We have to assume that both bodies are initially moving along the same straight line in opposite directions, so the collision is "head on". We also have to assume that the collision is "elastic", meaning that none of the original kinetic energy is lost to heat. The final momentum is 20 Kg-m/s in the direction opposite to the original 80 kg-m/s motion.
If you want to have that in meters per second square, convert the speed to meters per second (divide by 3.6 in this case). Then, divide the speed by the time.
The magnitude of momentum is directly proportional to speed. A car moving at 100 km per hr has 5 times as much momentum as a car with equal mass moving at 20 km per hr has.
momentum is mass x velocity. Even though the car is moving ten times faster, the ship mass is hundreds of times more, so the ship has more momentum
100 Kg-m/s
A small object can have the same momentum as a large object if the small object is moving at a significantly higher velocity than the large object. Momentum is the product of an object's mass and velocity, so a small object with a very high velocity can have the same momentum as a large object moving at a lower velocity.
An object at rest. Actually that's the only possible example for a single object. For two objects, you can have objects moving in opposite directions; for example, one may have a momentum of +100 units, and the other, a momentum of -100 units.
The momentum of an object is given by the product of its mass and velocity. In this case, the 3000 kg mass moving at 0.2 m/s has a big momentum because both its mass and velocity are relatively large. The momentum of an object is a measure of its motion and its resistance to changes in motion.
A moving automobile would have a greater momentum than a heavy truck at rest. Momentum is the product of mass and velocity, so even if the truck has more mass, the automobile's momentum would be greater due to its velocity.
-75
The formula is...momentum=velocity x massSo...momentum= 4m/s x 100kgmomentum= 400 kg m/s
First of all, a football player who's moving at 7 miles per second has more to worryabout than his momentum. That's 25,200 miles an hour, and if somebody doesn'tgrab him, and his helmet doesn't burst into flame from the atmospheric friction,he's going to leave the end-zone and go into low-earth orbit.But we'll just do the math.Momentum = (mass) x (speed)which is easy enough, but we have to make sure that all the units are in the samesystem. Right now they're not, so we have to remember to convert that "7 miles"into meters.Momentum = (100 kg) x (7 mi/sec) x (1,609.344 meter/mile) = 1,126,540.8 kg-m/secThat's roughly the same momentum as a 28-ton truck moving at 100 mph.
I believe at higher speeds there will be more air resistance.
100 kph