mass
The direction of an object's momentum is the same as its velocity. Momentum is a vector quantity that takes into account both an object's mass and its velocity, so a change in velocity will result in a change in momentum.
a moving objects momentum
Use the symbols 'm' for the object's mass, and 'v' for its velocity. Momentum is defined as 'mv' = the product of the object's mass and velocity. If the velocity doubles, then the new momentum is 'm' times '2v' = 2mv = 2 times (mv). This is just double the original momentum. So you can see that the magnitude of momentum is directly proportional to the magnitude of velocity, provided the mass remains constant.
Yes, an object's momentum changes when it slows down. Momentum is calculated as the product of an object's mass and velocity, so any change in velocity, such as slowing down, will result in a change in momentum.
No.....because we need both mass and velocity to find the momentum if velocity is same that is 9.8m/s that is of free falling bodies.........mass will effect the final result.
The direction of an object's momentum is the same as its velocity. Momentum is a vector quantity that takes into account both an object's mass and its velocity, so a change in velocity will result in a change in momentum.
a moving objects momentum
Use the symbols 'm' for the object's mass, and 'v' for its velocity. Momentum is defined as 'mv' = the product of the object's mass and velocity. If the velocity doubles, then the new momentum is 'm' times '2v' = 2mv = 2 times (mv). This is just double the original momentum. So you can see that the magnitude of momentum is directly proportional to the magnitude of velocity, provided the mass remains constant.
Yes, an object's momentum changes when it slows down. Momentum is calculated as the product of an object's mass and velocity, so any change in velocity, such as slowing down, will result in a change in momentum.
No.....because we need both mass and velocity to find the momentum if velocity is same that is 9.8m/s that is of free falling bodies.........mass will effect the final result.
If the mass stays the same but the velocity is increased, the momentum of the object will also increase. Momentum is directly proportional to velocity, so an increase in velocity will result in a proportionate increase in momentum.
Yes, if a moving object's velocity decreases, its momentum will also decrease as momentum is directly proportional to velocity. Momentum is calculated as mass multiplied by velocity, so any change in velocity will result in a change in momentum in the same direction.
If the momentum of an object changes and its mass remains constant, then there must have been a change in the object's velocity. This relationship is described by the formula: momentum = mass x velocity. Changing the velocity will result in a change in momentum.
If a body's velocity is doubled, its momentum will also double, assuming that the mass remains constant. Momentum is directly proportional to velocity, so an increase in velocity will result in a corresponding increase in momentum.
It's the mass of a object on its velocity (the velocity is a vector and as result of multiplication of a scalar (mass) on a vector (velocity) you get a vector (momentum). Intuitively, momentum is the property of a body which enables it to resist a force.
The momentum of an object is affected by its mass and velocity. Momentum is directly proportional to both mass and velocity, so an increase in either will result in an increase in momentum, and vice versa.
To increase the momentum of an object, you can either increase its mass or increase its velocity. Momentum is the product of an object's mass and its velocity, so changing either of these factors will result in a change in momentum.