A simple pendulum has a bob with mass m and charge q. The pendulum string has negligible mass. When a uniform and horizontal electric field E is applied, the tension in the string changes. The final tension in the string, when pendulum attains an equilibrium position is _____.
(g: acceleration due to gravity)
A
m2g2−q2E2
B
m2g2+q2E2
C
mg+qE
D
mg−qE
Answer
Correct answer:B
Step-by-step solution
Standard Method
Given: A simple pendulum bob has mass m and charge q. A uniform horizontal electric field E is applied, and gravitational acceleration is g.
Find: The final tension T in the string when the pendulum is in equilibrium.
At equilibrium, the bob experiences two perpendicular forces:
Gravitational force mg vertically downward
Electric force qE horizontally
The tension balances the resultant of these two forces.
T=(mg)2+(qE)2
Therefore,
T=m2g2+q2E2
Therefore, the correct option is B.
Force Balance Explanation
Given: The bob is under the action of gravity and a horizontal electric force.
Find: The magnitude of the string tension at equilibrium.
Step 1: Identify forces acting on the bob.
The bob experiences:
Gravitational force mg vertically downward
Electric force qE horizontally
Step 2: Condition of equilibrium.
At equilibrium, the string tension must balance the vector sum of these two mutually perpendicular forces.
Using Pythagoras theorem,
T=(mg)2+(qE)2
So,
T=m2g2+q2E2
Hence, the final tension is m2g2+q2E2.
Common mistakes
Treating mg and qE as forces in the same direction and writing T=mg+qE. This is wrong because gravity acts vertically while electric force acts horizontally. Instead, take the resultant using perpendicular vector addition.
Using T=mg−qE or m2g2−q2E2. This is incorrect because the forces do not oppose each other along one line. Instead, use Pythagoras theorem for the two perpendicular forces.
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