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Force is equal to mass times acceleration. This is Newton's Second Law.
The Force of friction is equal to the coefficient of friction times the normal force. Since normal force is equal to mass times the acceleration of gravity (9.8 m/s2), the force of friction is directly proportional to the mass.
F=ma Force equals its mass times its acceleration.
Work. The force times the distance over which the force is applied is equal to the work. Work is measured in joules.
The force of gravity (or any force) obey's Newton's Second Law of motion: the force applied to a body is equal to the time derivative of it's momentum. In cases where the mass is constant (practically all of introductory physics and much of graduate-level physics), force is equal to mass times acceleration. (F = ma)
force
accelleration=force divided by mass force=mass times aceleration
Inertia
Force is equal to mass times acceleration. This is Newton's Second Law.
Newton's Second Law is usually written as:force = mass x acceleration (Note: This is not the original form of the law, but the two forms are closely related.)
The Force of friction is equal to the coefficient of friction times the normal force. Since normal force is equal to mass times the acceleration of gravity (9.8 m/s2), the force of friction is directly proportional to the mass.
Force is equal to mass times acceleration. Mass is equal to density times volume. Acceleration equals to velocity over unit time.
The force on a large mass is greater, but it requires a larger force to accelerate a larger mass so the aceleration becomes the same. Force = mass x acceleration. But force of gravity =mg, therefore mg =ma, so a=g.
Correct! You've really nailed it.
F=ma Force equals its mass times its acceleration.
[ force ] = [ mass ] [ acceleration ] = [ mass ] [ length/time2 ] = [ mass-length-time-2 ]
Take a look at Newton's Second Law: F=ma (force = mass x acceleration). Solving for acceleration: a=F/m. In other words, if the force is the same, more mass will result in less acceleration, since the mass is in the denominator.