With a given braking system (car or rocketship), the system has to dissipate the Kinetic energy of the object. Kinetic formula for K.E. is 1/2MV2 (that 2 means squared). Therefore, the stopping distance increases linearly with the MASS.
Another way to look at it is the Force required to stop the MASS, which is:
F=M x A, so again as MASS increases the required Force increases Linearly.
The faster you are going the longer the stopping distance is.
The slower you are going the shorter the stopping distance is.
E.G.
Speed of a car Thinking distace Breaking distance Total stopping distance
mph meters meters meters
30 9 14 23
40 12 24 36
50 15 38 53
70 21 75 96
Affirmative.
More massive bodies will have greater stopping distance than less massive, given they are travelling with the exact same speed. This is due body's inertial forces.
For example, take a very large balloon and a truck. If you were to push the balloon and the truck to go with the same velocity, and then try to stop them, it would take you a lot longer to stop the truck then the balloon, because it is much heavier.
Well think of it this way. Basically, mass sort of "attracts" gravity, so the more mass an object has, the more pull gravity has. Therefore, the stopping distance being shorter.
I would imagine this is more about the energy required to move a larger force remains as moments of inertia. The more energy carried by an object with greater mass requires a greater force to stop it.
Kinetic energy is 0.5 m v2, so by doubling your speed, you quadruple your energy. Triple your speed, and your energy is nine times. It should be fairly obvious what the impact to braking distance would be.
No
Mass of object and distance from it
To know the speed of an object we need to know the distance the object travels and the time it takes. The object's mass is not needed. Since we do no know the distance in this case, we cannot solve to find its speed.
"Does The Height of an Object Affect its mass?"*short answer - no. longer answer - mass is constant for a given object... WEIGHT is what changes at different heights above earth.*learn to spell, noob!
mass multiplied by velocity gives momentum.
F is force and it is equal to the gravitational constant times the mass of the first object times the mass of the second object divided by the distance between the two squared.
-- The mass of one object. -- The mass of the other object. -- The distance between their centers of mass.
Mass of the first object, mass of the second object, distance between the objects.
Mass doesn't change. Mass the is substance of an object, moving it around won't affect how much mass it has, only adding or subtracting from the object would affect the quantity of mass. The weight would change because gravity is inversely proportional to distance but not the mass.
Catapult and not canapult. Any way for a given energy as mass of the object increases then distance would get decreased as velocity gets reduced.
The greater the mass of the car and its occupants the longer the stopping distance that is required for the vehicle. Stopping distance is calculated by taking into account car mass and reaction time in braking
The mass of the first object; the mass of the second object; the distance between them.The mass of the first object; the mass of the second object; the distance between them.The mass of the first object; the mass of the second object; the distance between them.The mass of the first object; the mass of the second object; the distance between them.
In zero gravity, the mass of an object does not effect the distance an object travels at all unless there is a constent force acting upon it. However, if it is in contact with another object, and gravity is what keeps the 2 or more objects touching each other, then mass will effect the distance it travels because of friction.
The mass of the object that is exerting the force and the distance between the two objects.
The mass of the object, the mass of the object that is attracting it and the distance between their centres of gravity.So your weight on the moon will depend on your mass, the moon's mass and the distance from your centre of gravity to the moon's.The mass of the object, the mass of the object that is attracting it and the distance between their centres of gravity.So your weight on the moon will depend on your mass, the moon's mass and the distance from your centre of gravity to the moon's.The mass of the object, the mass of the object that is attracting it and the distance between their centres of gravity.So your weight on the moon will depend on your mass, the moon's mass and the distance from your centre of gravity to the moon's.The mass of the object, the mass of the object that is attracting it and the distance between their centres of gravity.So your weight on the moon will depend on your mass, the moon's mass and the distance from your centre of gravity to the moon's.
The distance doesn't depend on the mass.
more mass means more inertia, inertia refers the a objects resistance to begin moving or to stop moving, therefore yes it does
The amount of mass of the object and other objects near by, as well as distance to the other objects.