student654321 said:
I've been trying to derive the Roche Limit and have been successful for the most part but out of curiosity i was wondering how the tidal force equation was derived to be: -2GMmr/d^3 ??
The tidal force is the difference between the gravitational forces at 2
different distances:
[tex]
F_{tidal} =\frac{GMm}{d^2}-\frac{GMm}{\left( {d+\Delta r} \right)^2}[/tex]
Find a common denominator
[tex]
F_{tidal} =\frac{GMm\left( {d+\Delta r} \right)^2-GMmd^2}{d^2\left( <br />
{d+\Delta r} \right)^2}[/tex]
FOIL the [tex](d+\Delta r)^2[/tex] 's
[tex]
F_{tidal} =\frac{GMm\left( {d^2+2\Delta rd+\Delta r^2} <br />
\right)-GMmd^2}{d^2\left( {d^2+2\Delta rd+\Delta r^2} \right)}[/tex]
Factor out [tex]GMm[/tex]
[tex]
F_{tidal} =GMm\frac{d^2+2\Delta rd+\Delta r^2-d^2}{d^4+2\Delta <br />
rd^3+d^2\Delta r^2}[/tex]
[tex]d^2[/tex] and [tex]-d^2[/tex] cancel each other
[tex]
F_{tidal} =GMm\frac{\rlap{--} {d}^{\rlap{--} {2}}+2\Delta rd+\Delta <br />
r^2-\rlap{--} {d}^{\rlap{--} {2}}}{d^4+2\Delta rd^3+d^2\Delta r^2}[/tex]
[tex]
F_{tidal} =GMm\frac{2\Delta rd+\Delta r^2}{d^4+2\Delta rd^3+d^2\Delta r^2}[/tex]
Eliminate that which is not significant. Take advantage that d >> r
[tex]
F_{tidal} =GMm\frac{2\Delta rd+\rlap{--} {\Delta }\rlap{--} {r}^{\rlap{--} <br />
{2}}}{d^4+\rlap{--} {2}\rlap{--} {\Delta }\rlap{--} {r}\rlap{--} <br />
{d}^{\rlap{--} {3}}+\rlap{--} {d}^{\rlap{--} {2}}\rlap{--} {\Delta <br />
}\rlap{--} {r}^{\rlap{--} {2}}}[/tex]
[tex]
F_{tidal} =GMm\frac{2\Delta rd}{d^4}[/tex]
Cancel the d the numerator with one of the d's in the denominator
[tex]
F_{tidal} =GMm\frac{2\Delta r\rlap{--} {d}}{d^{\rlap{--} {4}3}}[/tex]
[tex]
F_{tidal} =GMm\frac{2\Delta r}{d^3}[/tex]
Rearrange it to look like the formula in your post.
[tex]
F_{tidal} =\frac{2GMmr}{d^3}[/tex]
I don't get the negative sign that you get.