Two immiscible liquids of densities d and 2d are taken in a cylindrical vessel with equal heights each h. The velocity efflux of the liquid coming out of the hole made to the wall of the vessel at its bottom is

Two immiscible liquids of refractive index sqrt 2 and 2sqrt2 are filled with equal height h in a vessel. Then apparent depth of bottom surface of the container given that outside medium is air

Equal volumes of two immiscible liquids of densities rho and 3rho are filled in a big vessel. Two small holes are punched at depth h//3 and 4h//3 from upper surface of lighter liquid. If v_(1) and v_(2) are velocities of efflux at these two holes, then v_(1)//v_(2) is

A vessel is filled with two different liquids of densities rho and 2 rho respectively as shown in the figure. The velocity of flow of liquid through a hole at height (h)/(2) from bottom is

A liquid is filled in a vessel and a hole is made at a depth h below the free surface of the liquid. Statement-1 : Greater is the distance of the hole form the free surface of liquid, greater will be the velocity of efflux. And Statement-2 The speed of the liquid coming out of the orifice depends on the quantity of liquid in the vessel.

Equal volumes of two immiscible liquids of densities rho and 2 rho are filled in a vessel as shown in figure. Two small holes are punched at depth h/2 and 3h/2 from the surface of lighter liquid. If v_(1) and v_(2) are the velocities of efflux at these two holes then ((v_(2))/(v_(1)))^(2) is

Equal volume of two immiscible liquids of densities rho and 2rho are filled in a vessel as shown in the figure. Two small holes are punched at depths h//2 and 3h//2 from the surface of lighter liquid. If v_(1) and v_(2) are the velocities of efflux at these two holes, then v_(1)//v_(2) is

To what height h should a cylindrical vessel of diameter d be filled with a liquid so that the total force on the vertical surface of the vessel be equal to the force on the bottom-

Some liquid is filled in a cylindrical vessel of radius R. Let F_(1) be the force applied by the liquid on the bottom of the cylinder. Now the same liquid is poured into a vessel of uniform square cross-section of side R. Let F_(2) be the force applied by the liquid on the bottom of this new vessel. (Neglect atmosphere pressure). Then