The answer is force because Force is needed to change the direction of a moving mass.
no
as distance increases gravity's force decreases as mass increases gravity's force increases
The two factors are 1. the mass of the object, and 2. the force exerted on it.
force=mass*acceleration Therefore acceleration = force/mass This means you can change an objects acceleration in two ways, either by applying a force to the object (for example pushing a shopping trolly). You can also change the acceleration of an object by changing the mass of the object (putting shopping in the shopping trolly)
The answer is force because Force is needed to change the direction of a moving mass.
no
no
You cannot. Force = Mass*Acceleration or Mass*Rate of change of Velocity.
The Law of Applied Force states that a body's change in mass is proportional to the amount of force applied to it.
Force equals the mass times the rate of change of the velocity.
Mass and Force have no relationship except the gravitational force that is dependent on the mass of the body. Mass affects only the inertial force. Inertial force is the force required to change a state of rest or motion of a body. Greater the mass greater the inertial force required.
as distance increases gravity's force decreases as mass increases gravity's force increases
The two factors are 1. the mass of the object, and 2. the force exerted on it.
Going back to the equation F=m·a you can see that if the force changes but the mass does not, accelleration will change as well. If mass and force do not change, accelleration will be constant.
The correct question if Force due to Gravity varies directly with mass. As mass increase the Force due to gravity increases linearly.
Gravitational force does not change the mass (kilograms)of an object. It merely changes the force at which one object is attracted to the other. This means it's weight (newtons) is raised. The formula for weight is Mass x Force of Gravity, which is why thing seem to weigh less on the moon, their mass does not change, only their apparent weight.