Question:
A straight rod of length $L$ extends from $x = a$ to $x = L + a$. The gravitational force is exerts on a point mass $'m'$ at $x = 0$, if the mass per unit length of the rod is $A + Bx^2$, is given by:
A straight rod of length $L$ extends from $x = a$ to $x = L + a$. The gravitational force is exerts on a point mass $'m'$ at $x = 0$, if the mass per unit length of the rod is $A + Bx^2$, is given by:
Updated On: Oct 10, 2024
- $Gm\left[A\left(\frac{1}{a + L} - \frac{1}{a}\right) - BL\right]$
- $Gm\left[A\left(\frac{1}{a} - \frac{1}{a + L}\right) + BL\right]$
- $Gm\left[A\left(\frac{1}{a + L} - \frac{1}{a}\right) + BL\right]$
- $Gm\left[A\left(\frac{1}{a} - \frac{1}{a + L}\right) - BL\right]$
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The Correct Option is B
Solution and Explanation
$dm =\left(A+Bx^{2}\right)dx$
$ dF = \frac{GMdm}{x^{2}} $
$ =F = \int^{a+L}_{a} \frac{GM}{x^{2}}\left(A +Bx^{2}\right)dx $
$ =GM \left[- \frac{A}{x}+Bx\right] ^{a+L}_{a} $
$ =GM\left[A \left(\frac{1}{a} -\frac{1}{a+L}\right) +BL \right]$
$ dF = \frac{GMdm}{x^{2}} $
$ =F = \int^{a+L}_{a} \frac{GM}{x^{2}}\left(A +Bx^{2}\right)dx $
$ =GM \left[- \frac{A}{x}+Bx\right] ^{a+L}_{a} $
$ =GM\left[A \left(\frac{1}{a} -\frac{1}{a+L}\right) +BL \right]$
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Concepts Used:
Gravitation
In mechanics, the universal force of attraction acting between all matter is known as Gravity, also called gravitation, . It is the weakest known force in nature.
Newton’s Law of Gravitation
According to Newton’s law of gravitation, “Every particle in the universe attracts every other particle with a force whose magnitude is,
- F ∝ (M1M2) . . . . (1)
- (F ∝ 1/r2) . . . . (2)
On combining equations (1) and (2) we get,
F ∝ M1M2/r2
F = G × [M1M2]/r2 . . . . (7)
Or, f(r) = GM1M2/r2
The dimension formula of G is [M-1L3T-2].