The frequency of sonometer wire is f. The frequency becomes `f//2` when the mass producing the tension is completely immersed in water and on immersing the mass in a certain liquid, frequency becomes `f//3`. The relative density of the liquid is

the frequency of a sonometer wire is 100 Hz. When the weight producing th tensions are completely immersed in water the frequency becomes 80 Hz and on immersing the weight in a certain liquid the frequency becomes 60 Hz. The specific gravity of the liquid is

A piece of steel has a weight w in air, w_(1) when completely immersed in water and w_(2) when completely immersed in an unknown liquid. The relative density (specific gravity) of liquid is

A piece of steel has a weight w in air, w_(1) when completely immersed in water and w_(2) when completely immersed in an unknown liquid. The relative density (specific gravity) of liquid is

A certain block weighs 15 N in air. But is weighs only 12 N when completely immersed in water. When immersed completely in another liquid, it weighs 13 N. Calculate the relative density of (i) the block and (ii) the liquid.

A stone is hung from a sonometer wire. If the stone is immersed in water the fundamental frequency

A piece of stone of mass 15.1 g is first immersed in a liquid and it weighs 10.9 gf. Then on immersing the piece of stone in water, it weighs 9.7 gf. Calculate the relative density of the liquid.

How does the frequency of a vibrating wire change when the attached load is immersed in water.

The focal length of a convex lens of R.I. 1.5 is f when it is placed in air. When it is immersed in a liquid is behaves as a converging lens its focal length becomes xf(x gt 1) . The refractive index of the liquid

A wire is suspended vertically from a rigid support. When loaded with a steel weight in air, the wire extends by 16cm . When the weight is completely immersed in Water, the extension is reduced to 14 cm . The relative density of the material of the weight is