Question about Inertia

Macrobe

I have a question regarding Inertia. Exactly how much force, in Newtons, is required to overcome the inertia of exactly one kilogram of mass? It seems to me there must be some sort of quantity for it.

LastOneStanding

It depends on how fast you want to accelerate the object. The equation is ##\vec{F_{Net}} = m\vec{a}##, or in words, (net force acting on the object) = (mass of the object) x (acceleration of the object). This is Newton's second law. It takes, for example, 1 Newton of force to accelerate a 1kg object at 1m/s².

Macrobe

Ah. Okay...not exactly what I was looking for, but what I was looking for was probably wrong ;) thanks.

LastOneStanding

Yes, if you were looking for some measure of a force required to overcome inertia that is independent of acceleration, then there's no such thing.

BruceW

yeah, it is pretty counter-intuitive that f=ma, because in our everyday lives, most of the time there are frictional forces.

Tik

I think Macrobe meant to ask how much force would be required to get a body off its stationary position. On a flat surface, it is equal to the co-efficient of static friction x Weight of the body (weight, not mass). If the body is on, say, a road, the force required to get the body would be around 0.7 times the weight of the body.

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Macrobe	Question about Inertia Tweet I have a question regarding Inertia. Exactly how much force, in Newtons, is required to overcome the inertia of exactly one kilogram of mass? It seems to me there must be some sort of quantity for it.

LastOneStanding	It depends on how fast you want to accelerate the object. The equation is ##\vec{F_{Net}} = m\vec{a}##, or in words, (net force acting on the object) = (mass of the object) x (acceleration of the object). This is Newton's second law. It takes, for example, 1 Newton of force to accelerate a 1kg object at 1m/s².

LastOneStanding	Question about Inertia Yes, if you were looking for some measure of a force required to overcome inertia that is independent of acceleration, then there's no such thing.

BruceW Recognitions: Homework Help	yeah, it is pretty counter-intuitive that f=ma, because in our everyday lives, most of the time there are frictional forces.