Draw a schematic diagram of Cavendish's experiment for the determination of the universal gravitational constant $G$ and obtain the formula used in it.
(N/A) The value of the gravitational constant $G$ can be determined experimentally,which was first done by Cavendish in $1798$. The apparatus used is schematically shown in the figure.
The bar $AB$ has two small lead spheres attached at its ends. The bar is suspended from a rigid support by a fine wire.
Two large lead spheres are brought close to the small ones but on opposite sides. The big spheres attract the nearby small ones by equal and opposite forces. There is no net force on the bar,but there is a torque equal to $F \times L$,where $F$ is the force of attraction between a big sphere and a small sphere,and $L$ is the length of the bar. As a result,the bar rotates about the wire $OM$. The wire gets twisted until the restoring torque of the wire equals the gravitational torque.
In this equilibrium position,the angle of twist $\theta$ is measured. If $k$ is the torsion constant of the wire,the restoring torque is $\tau = k\theta$.
Gravitational force on each small sphere is $F = \frac{GMm}{d^2}$,where $M$ is the mass of the large sphere,$m$ is the mass of the small sphere,and $d$ is the distance between their centers.
The gravitational torque is $\tau_g = F \times L = \frac{GMm}{d^2} L$.
At equilibrium,$\tau_g = \tau$,so $\frac{GMm}{d^2} L = k\theta$.
Thus,$G = \frac{k\theta d^2}{MLm}$.
The bar $AB$ has two small lead spheres attached at its ends. The bar is suspended from a rigid support by a fine wire.
Two large lead spheres are brought close to the small ones but on opposite sides. The big spheres attract the nearby small ones by equal and opposite forces. There is no net force on the bar,but there is a torque equal to $F \times L$,where $F$ is the force of attraction between a big sphere and a small sphere,and $L$ is the length of the bar. As a result,the bar rotates about the wire $OM$. The wire gets twisted until the restoring torque of the wire equals the gravitational torque.
In this equilibrium position,the angle of twist $\theta$ is measured. If $k$ is the torsion constant of the wire,the restoring torque is $\tau = k\theta$.
Gravitational force on each small sphere is $F = \frac{GMm}{d^2}$,where $M$ is the mass of the large sphere,$m$ is the mass of the small sphere,and $d$ is the distance between their centers.
The gravitational torque is $\tau_g = F \times L = \frac{GMm}{d^2} L$.
At equilibrium,$\tau_g = \tau$,so $\frac{GMm}{d^2} L = k\theta$.
Thus,$G = \frac{k\theta d^2}{MLm}$.
Explore More
Similar Questions
If the distance between two masses is doubled,the gravitational attraction between them
Easy
View Solution$A$ mass $M$ at rest is broken into two pieces having masses $m$ and $(M-m)$. The two masses are then separated by a distance $r$. The gravitational force between them will be maximum when the ratio of the masses $[m : (M-m)]$ of the two parts is:
MediumWBJEE 2013
View SolutionFour identical particles of mass $m$ are kept at the four corners of a square. If the gravitational force exerted on one of the masses by the other masses is $\left(\frac{2 \sqrt{2}+1}{32}\right) \frac{Gm^2}{L^2}$,the length of the sides of the square is
DifficultJEE MAIN 2024
View SolutionAre the inertial mass and gravitational mass of a body different from each other?
Easy
View SolutionThe gravitational force between two objects is $1 \ N$. If the distance between the two objects is doubled,what will be the new gravitational force between them (in $N$)?
Medium
View SolutionVedclass Products
For Students
Vedclass Test Series
Mock tests in real JEE/NEET style with performance analysis. 5-day free trial.
Start Free TrialFor Teachers
Exam Paper Generator
Generate Set A/B/C/D exam papers from 7.5L+ questions in 2 minutes. 3 chapters free.
Try FreeFor Institutes
Online Exam Module
Live online exams with unlimited students, 360° analytics & white-label branding.
See Demo