Question

An oil drop having charge `q` and apparent weight `W` falls with a terminal speed `v` in the absence of electric field. When electric field is switched on it starts moving up with terminal speed `v`. The strength of the electric field is ??

Answer 1

The drag force acting upon the oil drop is calculated from Stoke's law and is given as

`F_d=6pietarv` ......(1)

The apparent weight for a perfectly spherical body is given by
True weight `-` Upthrust (Weight of fluid displaced by the body)

`F_barg=W` .....(2)

At terminal velocity the oil drop is not accelerating as the net force acting on it must be zero

`F_d-F_barg=0`

Hence equating (1) and (2) we get

`W=6pietarv_(Tdarr)` ......(3)
where `r`-radius of oil drop, `η`-viscosity of air, `v_(Tdarr)`-terminal velocity.

When electric field `E` is switched on the oil drop starts moving up with terminal speed `v_(Tuarr)`.

Electric force will act upwards, net gravity and drag forces acts downwards. Net force acting on the oil drop is again zero.

`F_e-F'_d-F_barg=0`
`=>F_e=F'_d+F_barg=0`

where `F'_d` is the new drag force under the action of electric field.

Inserting various values above expression becomes

`qE=6pietarv_(Tuarr)+W`

Given `v_(Tuarr)and v_(Tdarr)=v`

`:.qE=W+W`
`=>E=(2W)/q` ......(4)

.-.-.-.-.-.-.-.-.-.-.-.-.-.-.-

Apparent weight in terms of other variables.

`F_barg=4/3pir^3g(rho-rho_(air))=W` .....(2)

Hence equating (1) and (2) we get

`r^2=(9etav_(Tdarr))/(2g(rho-rho_(air))` ......(3)
where `r`-radius of oil drop, `η`-viscosity of air, `v_(Tdarr)`-terminal velocity, `g`- acceleration due to gravity, `ρ`-density of oil and `ρ_(air)`-density of air