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. `3.98 xx 10^(-4) J`B. `8.46 xx 10^(-4) J`C. `3.98 xx 10^(-2) J`D. `8.46 xx 10^(-2) J`

A mercury drop of radius 1.0 cm is sprayed into `10^(6)` droplets of e

1.	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. `3.98 xx 10^(-4) J`B. `8.46 xx 10^(-4) J`C. `3.98 xx 10^(-2) J`D. `8.46 xx 10^(-2) J`
Answer» Correct Answer - C Let r be the radius of one droplet. Now, `(4)/(3)pi R^(3) = 10^(6) xx (4)/(3)pi r^(3)` `rArr r = (R)/(100) = (1)/(100) cm = 10^(-4) m` `A_(i) = 4pi R^(2)` and `A_(f) = 10^(6) xx 4pi r^(2)` Change in area, `Delta A = A_(f) = A_(i) = 4pi xx 99 xx 10^(-4) m^(2)` Increases in surface energy `= S Delta A = 32 xx 10^(-2) xx 4pi xx 99 xx 10^(-4) J = 3.98 xx 10^(-4) m^(2)` Increase in surface energy `= S Delta A = 32 xx 10^(-2) xx 4pi xx 99 xx 10^(-4) J = 3.98 xx 10^(-2) J` The increase in surface energy is on the expense of internal energy, so expended `= 3.98 xx 10^(-2) J`

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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. `3.98 xx 10^(-4) J`B. `8.46 xx 10^(-4) J`C. `3.98 xx 10^(-2) J`D. `8.46 xx 10^(-2) J`

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