Apply maximum force for the longest possible time interval
The object with the greatest momentum in table 3-1 is the truck, which has a mass of 8000 kg and a velocity of 20 m/s. Momentum is calculated by multiplying an object's mass by its velocity, so the truck's momentum would be the product of these values, which is 160,000 kg*m/s.
An object with the least momentum would be one that is either stationary or moving very slowly. Momentum is the product of an object's mass and velocity, so an object with a small mass and low speed would have the least momentum.
The force would be greatest when the object has the greatest mass and acceleration, following Newton's second law which states F = ma. Initially, the force could also be greatest during impact or collision when the object experiences a sudden change in momentum.
Momentum is mass multiplied by velocity - so it is proportional to the velocity. If the velocity triples then so does the momentum
An object with the least mass and velocity would have the least momentum.
In order to impart the greatest momentum to an object, you should both exert the largest force possible upon the object in question and extend that force for as long as possible. This is so because the greater the force acting on an object results in a greater change in velocity, which in turn yields a greater momentum. In addition to exerting the largest force possible on an object, you should also extend that force over the longest period of time as possible, as the sustained force also produces more momentum. As p= m•v, the best method in obtaining the greatest amount for 'p' would be to manipulate either the 'm' or 'v' variables. Force= acceleration= change in velocity= MOMENTUM. Greater amount of time= MOMENTUM
The object with the greatest momentum in table 3-1 is the truck, which has a mass of 8000 kg and a velocity of 20 m/s. Momentum is calculated by multiplying an object's mass by its velocity, so the truck's momentum would be the product of these values, which is 160,000 kg*m/s.
An object with the least momentum would be one that is either stationary or moving very slowly. Momentum is the product of an object's mass and velocity, so an object with a small mass and low speed would have the least momentum.
The force would be greatest when the object has the greatest mass and acceleration, following Newton's second law which states F = ma. Initially, the force could also be greatest during impact or collision when the object experiences a sudden change in momentum.
Momentum is mass multiplied by velocity - so it is proportional to the velocity. If the velocity triples then so does the momentum
An object with the least mass and velocity would have the least momentum.
The momentum of an object is calculated as the product of its mass and velocity. So, the momentum of a 3kg object moving at 5m/s would be 15 kg*m/s.
The momentum of an object is calculated by multiplying its mass by its velocity. In this case, the momentum of a 9kg object moving at 1.5m/s would be 13.5 kg*m/s.
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.
No, since work is required for an object to gain momentum. In this case, if no work was done (work=force x distance), then the object would not gain momentum despite the force being exerted on it.
An object with a small mass and low velocity would have the least momentum. Momentum is the product of an object's mass and velocity, so a combination of low mass and low velocity would result in the least momentum.
A heavier ball traveling at a higher speed would have the most momentum. Momentum is the product of an object's mass and its velocity.