A mecury drop of radius 1 cm is sprayed into `10^(5)` droplets of equal size. Calculate the increase in surface energy if surface tension of mercury is `35xx10^(-3)N//m`.

A mercury drop of radius 1 cm is sprayed into 10^(6) droplets of equal size. Calculate the energy expended if surface tension of mercury is 35xx10^(-3)N//m .

A menisus drop of radius 1 cm sprayed into 10^(5) droplets of equal size . Calculate the energy expended if surface tension of mercury is 435 xx10^(-3) N/m

A mercury drop of radius 1.0 cm is sprayed into 10^(8) droplets of equal size. Calculate the energy expanded. (Surface tension of mercury = 32 xx 10^(-2) N//m ).

A mercury drop of radius R is sprayed into n droplets of equal size. Calculate the energy expanded if surface tension of mercury is T .

A mercury drop of radius 1.0 cm is sprayed into 10^(6) droplets of equal sizes. The energy expended in this process is (Given, surface tension of mercury is 32 xx 10^(-2) Nm^(-1) )

A mercury drop of radius R is sprayed into n droplets of equal size. Calculate the energy expended if surface tension of mercury is T .

A water drop of radius 10^-2 m is broken into 1000 equal droplets. Calculate the gain in surface energy. Surface tension of water is 0.075Nm^-1

A spherical mercury drop of 10^(-3)m radius is sprayed into million drops of the same size. Calculate the energy used in doing so. Given surface tension of mercury = 0.55 Nm^(-1)

A drop of mercury of radius 2 mm is split into 8 identical droplets. Find the increase in surface energy. Surface tension of mercury =0.465Jm^-2

A spherical drop of mercury of radius 3mm falls to the ground and breaks into 27 smaller drops of equal size. Calculate the amount of work done. Surfae tension of mercury = 0.472 Nm^(-1)