more energy would need to be added to the smaller mass to reach the same point. D = F X M (distance = force times mass) if distance is 100cm and mass of object is 30grams, it would be written - 100 = ? x 30 ( ? = 3.333) if distance is 100cm (remains the same) and mass is 50grams (larger this time) - 100 = ? x 50 ( ? = 2)
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.
The object's mass and weight determines the force and distance, the greater the force, the less distance it covers. However, when a knife cuts the object, it covers less force and more distance.
you would have to apply a correlated ammount of energy. Initially it will take more energy to move the heavier object but more to slow it down, for the smaller object it is vice versa.
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.
-- The mass of one object. -- The mass of the other object. -- The distance between their centers of mass.
Before you test it, you could state the hypothesis in two different ways You could say: "The mass of a falling object has no effect on the time it takes to fall some distance." Or you could say: "The time a falling object takes to fall some distance depends on its mass." You could use the same tests to investigate EITHER hypothesis. --------------------------- The mass of a falling object has no effect on the time it takes to fall some distance assuming zero air resistance.
An object's speed is (distance it travels) divided by (time to cover the distance). The object's mass doesn't matter at all.
You could use the terms mass, object, or body (that's what Newton used).
it is easier to see that when the volume of an object is so and so, it is this mass. because an object with more mass could have less volume than an object with larger volume.
An object which has a less mass or weight.
The mass and distance of an object fom another object