Two metal spheres of radius and have same surface charge density . If they are brought in contact and then separated, the surface charge density on smaller and bigger sphere becomes and , respectively. The ratio is:
- A
- B
- C
- D
Two metal spheres of radius and have same surface charge density . If they are brought in contact and then separated, the surface charge density on smaller and bigger sphere becomes and , respectively. The ratio is:
Correct answer:D
Standard Method
Given: Two metal spheres have radii and , and both initially have the same surface charge density .
Find: The ratio after the spheres are brought into contact and then separated.
Initial charges are obtained from surface charge density multiplied by surface area:
So, total charge is
When the spheres are brought into contact, their potentials become equal. For an isolated conducting sphere, potential is proportional to . Hence,
which gives
Using charge conservation,
Substituting ,
Therefore,
Now the final surface charge densities are
Hence,
Therefore, the correct option is D.
Charge shares in proportion to radius
Given: The initial surface charge density on both spheres is the same, and their radii are and .
Find: The ratio after contact and separation.
Since the initial surface charge density is the same, initial charges are proportional to surface areas:
So total charge is distributed over the two spheres after contact in the ratio of their radii, because equal potential implies charge proportional to radius:
Now surface charge density is charge divided by surface area. Therefore,
Using ,
Hence,
This shortcut works because after contact, the common potential condition makes the final charges proportional to sphere radii, not surface areas. Therefore, the correct option is D.
Using surface area ratio for the final charge distribution is incorrect. After contact, charges redistribute until potentials are equal, so final charges are proportional to radii, not to areas. Use .
Assuming equal final surface charge densities because the spheres were initially given the same is wrong. Once separated after contact, the two spheres carry different charges on different surface areas, so compute and separately.
Forgetting charge conservation leads to an incomplete solution. Even after applying equal potential, you must also use the total charge relation .
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