A cylindrical capacitor conneced to a `dc` voltage source `V` touches the surface of water with its end (Fig) The sepration `d` between the capacitors electrodes is substantially less than their mean radius. Find a height `h` to which the water level in the gap will rise. The, capilary effects are to be negelected.

A cylindrical capacitor conneced to a `dc` voltage source `V` touches

1.	A cylindrical capacitor conneced to a `dc` voltage source `V` touches the surface of water with its end (Fig) The sepration `d` between the capacitors electrodes is substantially less than their mean radius. Find a height `h` to which the water level in the gap will rise. The, capilary effects are to be negelected.
Answer» If `C_(0)` is the inital capacitance of the condenser before water rises in it then `U_(i) = (1)/(2) C_(0) V^(2)`, where `C_(0) = (epsilon_(0) 2l pi R)/(d)` (`R` is the mean radius and `l` is the length of the capacitor plates.) Suppose the liquid rises to a height `h` in it. Then the capacitance of the condenser is `C = (epsilon epsilon_(0)h 2pi R)/(d) + (epsilon(l-h) 2pi R)/(d) = (epsilon_(0) 2pi R)/(d) (l + (epsilon - 1) h)` and energy of the capacitor and the liquid (inculding both gravitational and electrostatic condtributions) is epsilon `(1)/(2) (epsilon_(0) 2pi R)/(d) (l + (epsilon - 1)h) V^(2) + rho g (2pi R hd) (h)/(2)` If the capacitor were not connected to a battery this energy would have to be minimized. But the capacitor is connected to the battery and in effect the potential energy of the capacitor and the liquid increases by `delta h ((epsilon_(0) 2pi R)/(2d) (epsilon - 1) V^(2) + rho g (2pi Rd) h)` and that of the cell diminishes by the quantity `A_(cell)` which is the product of charge flown and `V` `delta h (epsilon_(0) (2pi R))/(d) (epsilon - 1) V^(2)` In equilbrium, the two must balance, so `rho g dh = (epsilon_(0) (epsilon - 1) V^(2))/(2d)` Hence `h = (epsilon_(0) (epsilon - 1) V^(2))/(2rho g d^(2))`

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