That would depend on what you consider "large".
The size of an object's momentum = (its mass) x (its speed).
So, more mass and more speed result in more momentum.
The larger the momentum, the harder it will be to stop it. Thus, the larger the force needed to decelarate the object. Since momentum is directly proportional to the velocity, the larger the momentum, the larger the velocity.
False. Momentum is a product of an object's mass and velocity, so even if the object is small, it can have a large momentum if it has a high velocity. It doesn't need to be stationary to have a large momentum.
A slow-moving train has a large momentum because momentum is determined by both the mass and velocity of an object. Even though the train may be slow, its large mass contributes to a significant momentum. Momentum is a vector quantity that accounts for both the object's mass and its motion.
An object with momentum is hard to stop because momentum is a measure of how much motion an object has. When an object is in motion, it has momentum, and stopping it requires applying a force in the opposite direction. The greater the momentum of an object, the more force is needed to bring it to a stop.
Yes. Momentum is based on mass and velocity, not physical size. 1 kg of styrofoam moving at 100 m/s has the same momentum as 1 kg of gold moving at 100 m/s, but the piece of styrofoam will be over 1000 times the size. Additionally, since the formula for momentum is mass times velocity, a 10 kg piece of gold moving at 10 m/s has the same momentum as a 1 kg piece of gold moving at 100 m/s. They both have a momentum of 100 kg-m/s.
That would depend on what you consider "large".The size of an object's momentum = (its mass) x (its speed).So, more mass and more speed result in more momentum.
The momentum of an object is directly related to its stopping distance. A larger momentum means more force is needed to stop the object, resulting in a longer stopping distance. Conversely, a smaller momentum requires less force and results in a shorter stopping distance.
A freight train traveling at high speed will have the greatest momentum, as momentum is directly proportional to both an object's mass and its velocity. The large mass of the train combined with its high velocity results in a significant amount of momentum.
No, a stationary object does not have momentum because momentum is the product of an object's mass and its velocity. If an object is not moving (velocity is zero), then its momentum will also be zero.
An object does not have momentum when it is stationary or not in motion. Momentum is a product of an object's mass and velocity, so if either of these values is zero, the object's momentum will also be zero.
No, a resting object does not have momentum because momentum is the product of an object's mass and velocity. Since a resting object has zero velocity, its momentum is also zero.
To find the change in momentum of an object, you can subtract the initial momentum from the final momentum. Momentum is calculated by multiplying the mass of the object by its velocity. So, the change in momentum is the final momentum minus the initial momentum.