Momentum increases.
If the momentum of an object changes while its mass remains constant, then its velocity must have changed accordingly. This relationship is described by the equation momentum = mass x velocity. So, if momentum changes without a change in mass, then velocity must have changed.
If mass doubles, momentum also doubles as momentum is directly proportional to mass. This is because momentum is the product of an object's mass and its velocity, so if mass increases, momentum will increase as well.
If the mass of an object increases, its momentum also increases. Momentum is directly proportional to mass, so an increase in mass will result in a proportional increase in momentum, given that the velocity remains constant.
Momentum = mass x velocity. Here velocity is constant. So momentum is directly proportional to the mass. Hence as mass decreases momentum too decreases proportionaly. If mass is reduced to half of its original then momentum also gets reduced to half of its original
If an object's mass stays constant but its momentum is changing, then its velocity must be changing as well. This implies that there is an external force acting on the object, causing its momentum (mass multiplied by velocity) to change. This concept is described by Newton's second law of motion, which states that the rate of change of an object's momentum is equal to the force applied to it.
If the momentum of an object changes while its mass remains constant, then its velocity must have changed accordingly. This relationship is described by the equation momentum = mass x velocity. So, if momentum changes without a change in mass, then velocity must have changed.
If mass doubles, momentum also doubles as momentum is directly proportional to mass. This is because momentum is the product of an object's mass and its velocity, so if mass increases, momentum will increase as well.
If the mass of an object increases, its momentum also increases. Momentum is directly proportional to mass, so an increase in mass will result in a proportional increase in momentum, given that the velocity remains constant.
Momentum = mass x velocity. Here velocity is constant. So momentum is directly proportional to the mass. Hence as mass decreases momentum too decreases proportionaly. If mass is reduced to half of its original then momentum also gets reduced to half of its original
If an object's mass stays constant but its momentum is changing, then its velocity must be changing as well. This implies that there is an external force acting on the object, causing its momentum (mass multiplied by velocity) to change. This concept is described by Newton's second law of motion, which states that the rate of change of an object's momentum is equal to the force applied to it.
It increases
Momentum = mass x velocity. Using standard terminology, p = mv. Δp = m v - m0 v0 (Change in mass = mass x velocity - initial mass x initial velocity ) If your mass stays the same, this can be simplified to Δp = m ( v - v0 )
The velocity stays the same, it is constant
it stays the same
Velocity = Frequency * Wavelength. If the wavelength increases and the frequency stays the same, then the speed of the wave will increase.
In a collision between two billiard balls, momentum is conserved. This means that the total momentum of the two balls before the collision is equal to the total momentum after the collision. The momentum is transferred between the two balls during the collision, resulting in changes in their individual velocities.
Yes, according to the law of conservation of momentum, in a closed system the total momentum before a collision will equal the total momentum after the collision. Therefore, the total amount of momentum stays the same when objects collide.