Um i solve it using formulaTSny said:Hello and welcome to PF!
If you can work the problem for the case where all 6 drops initially have the same potential, then you should find that it's not much harder to deal with the case of different initial potentials.
Can you show how you get the answer when all 6 drops have the same initial potential?
I know but this methode only useful for similar charge only searched whole internet can't find right answer. All links leads to same potential problem only i tried it myself bt couldntTSny said:Do you understand how to derive the formula V = n2/3 vs for equal initial potentials?
If so, then you can use essentially the same method of derivation to get the result for unequal initial potentials.
If not, my hint would be to consider how the charge on a spherical drop is related to the potential and radius of the drop.
"Coalesce of mercury drops at different potential" refers to the process of two or more mercury drops coming together to form a larger drop when exposed to an electric field or varying voltage.
Studying the coalescence of mercury drops at different potential can provide insights into the behavior of liquid metals under electric fields, which is important in fields such as materials science and electrochemistry.
The potential, or voltage, applied to the mercury drops affects the magnitude of the electric field surrounding them. This electric field can cause the drops to attract and merge together, leading to coalescence.
The coalescence of mercury drops at different potential can be influenced by factors such as the size and shape of the drops, the surface tension of the mercury, and the presence of impurities or other substances in the surrounding environment.
Understanding the coalescence of mercury drops at different potential can have practical applications in fields such as microfluidics, where controlling the merging of liquid droplets is important for various processes and technologies.