Why is acceleration inversely proportional to mass?

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Why is acceleration inversely proportional to mass?

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Answer 1 · 2018-04-28T01:54:27

acceleration equals to the force applied divided by mass

Explanation:

an object moving at a velocity of x carries the force of its mass times its speed.

when you apply a force onto an object, the increase in speed of it would be affected by its mass. Think of it this way: you apply some force onto an iron ball, and apply the same force on a plastic ball (they are of equal volume). Which one moves faster, and which one moves slower? The answer is obvious: the iron ball will accelerate slower and travel slower, while the plastic ball is faster.

The iron ball has a greater mass, so the force which makes it accelerate is deduced more. The plastic ball has a smaller mass, so the force applied is divided by a smaller number.

I hope this helps you a bit.

Answer 2 · 2018-04-28T02:19:52

Assuming we're using $F = m a$ $F=ma$ , then it's because, when one goes up, the other must go down in order to keep the equation balanced.

Explanation:

Say we wish to keep a force $F$ $F$ exerted by an object constant. If the mass $m$ $m$ of the object doubles, what must happen to the object's acceleration $a$ $a$ to keep $F$ $F$ unchanged?

The answer is: the object's acceleration must be halved.

We start with

$F = m \cdot a$ $F=m*a$

and if we double the mass to $2 m$ $2m$ , the RHS as a whole has doubled. Thus, the LHS also doubles, meaning we get double the force:

$2 F = 2 m \cdot a$ $2F = 2m*a$

This is an example of direct proportionality between $F$ $F$ and $m$ $m$ . If $m$ $m$ doubles, $F$ $F$ responds by doubling as well.

But we want to keep the force the same; we don't want $2 F$ $2F$ , we want $F$ $F$ . So we need to divide the LHS by 2. And to do that, we must divide the RHS by 2 as well. So either the mass $2 m$ $2m$ goes back down to $m$ $m$ , or the acceleration $a$ $a$ gets cut to $\frac{1}{2} a$ $1/2 a$ .

$F = 2 m \cdot \frac{1}{2} a$ $F= 2m*1/2 a$

This is an example of inverse proportionality. When the force is taken as a constant, if mass doubles, acceleration must be halved.

Note:

You can also see the inverse relation between $m$ $m$ and $a$ $a$ by solving $F = m a$ $F=ma$ for one or the other.

$F = m a \Rightarrow a = \frac{F}{m} \Leftrightarrow a = F (m^{- 1})$ $F=ma " "=>" "a=F/m" " <=>" "a=F(m^-1)$

$F = m a \Rightarrow m = \frac{F}{a} \Leftrightarrow m = F (a^{- 1})$ $color(white)(F=ma) " "=>" "m=F/a" "<=>" "m=F(a^-1)$

It's now easy to see mathematically that $a$ $a$ and $m$ $m$ are inversely proportional, because each is a multiple of the other's inverse (that multiple being $F$ $F$ itself).

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Why is acceleration inversely proportional to mass?

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