Question 15 Marks
A cubical metal block of edge 12cm floats in mercury with one fifth of the height inside the mercury. Water is poured till the surface of the block is just immersed in it. Find the height of the water column to be poured. Specific gravity of mercury = 13.6.
Answer
View full question & answer→Length of the edge of the block $\rho_{\text{Hg}}=13.6\text{gm/cc}$ Given that, intialy $\frac{1}{5}$ of block is inside mercury. Let $\rho\text{b}\rightarrow$ density of block in gm/cc.$\therefore(\text{x})^2\times\rho_\text{b}\times\text{g}=(\text{x})^2\times\Big(\frac{\text{x}}{5}\Big)\times\rho_{\text{Hg}}\times\text{g}$
$\Rightarrow12^3\times\rho\text{b}=12^2\times\frac{12}{5}\times13.6$
$\Rightarrow\rho_\text{b}=\frac{13.6}{5}\text{gm}/\text{cc}$
After water poured, Let x = Height of water column.$\text{v}_\text{b}=\text{v}_\text{Hg}+\text{v}_\text{w}=12^3$
Where $\text{v}_\text{Hg}$ and $\text{v}_\text{w}$ are volume of block inside mercury and water respectively$\therefore(\text{v}_\text{b}\times\rho_\text{b}\times\text{g})=(\text{v}_\text{Hg} \times\rho_{\text{Hg}}\times\text{g})+(\text{v}_\text{w}\times\rho_\text{w}\times\text{g)}$
$\Rightarrow(\text{v}_\text{Hg}+\text{v}_\text{w})\rho_\text{b}=\text{v}_\text{Hg}\times\rho_{\text{Hg}}\times+\text{v}_\text{w}\times\rho_\text{w}.$
$\Rightarrow(\text{v}_\text{Hg}+\text{v}_\text{w})\times\frac{13.6}{5}=\text{v}_\text{Hg}\times13.6+\text{v}_\text{w}\times1$
$\Rightarrow(12)^2\times\frac{13.6}{5}=(12-\text{x})\times(12)^2\times13.6+(12)^2\times1$
$\Rightarrow\text{x}=10.4\text{cm}$
$\Rightarrow12^3\times\rho\text{b}=12^2\times\frac{12}{5}\times13.6$
$\Rightarrow\rho_\text{b}=\frac{13.6}{5}\text{gm}/\text{cc}$
After water poured, Let x = Height of water column.$\text{v}_\text{b}=\text{v}_\text{Hg}+\text{v}_\text{w}=12^3$
Where $\text{v}_\text{Hg}$ and $\text{v}_\text{w}$ are volume of block inside mercury and water respectively$\therefore(\text{v}_\text{b}\times\rho_\text{b}\times\text{g})=(\text{v}_\text{Hg} \times\rho_{\text{Hg}}\times\text{g})+(\text{v}_\text{w}\times\rho_\text{w}\times\text{g)}$
$\Rightarrow(\text{v}_\text{Hg}+\text{v}_\text{w})\rho_\text{b}=\text{v}_\text{Hg}\times\rho_{\text{Hg}}\times+\text{v}_\text{w}\times\rho_\text{w}.$
$\Rightarrow(\text{v}_\text{Hg}+\text{v}_\text{w})\times\frac{13.6}{5}=\text{v}_\text{Hg}\times13.6+\text{v}_\text{w}\times1$
$\Rightarrow(12)^2\times\frac{13.6}{5}=(12-\text{x})\times(12)^2\times13.6+(12)^2\times1$
$\Rightarrow\text{x}=10.4\text{cm}$