A uniform rod of density `rho` is placed in a wide tank containing a liquid of density `rho_0 (rho_0 gt rho)`. The depth of liquid in the tank is half the length of the rod. The rod is in equilibrium, with its lower end resting on the bottom of the tank. In this position the rod makes an angle `theta` with the horizontal.

A sealed tank containing a liquid of density rho moves with a horizontal acceleration a, as shown in the figure. The difference in pressure between the points A and B is

A sealed tank containing a liquid of density rho moves with a horizontal acceleration a, as shown in the figure. The difference in pressure between the points A and B is

A sealed tank containing a liquid of density rho moves with horizontal acceleration a as shown in the figure. The difference in pressure between two points A and B will be

A sealed tank containing a liquid of density rho moves with horizontal acceleration a as shown in the figure. The difference in pressure between two points A and B will be

A sealed tank containing a liquid of density rho moves with horizontal acceleration a as shown in the figure. The difference in pressure between two points A and B will be

A body of density rho is placed slowly on the surface of a liquid of density delta . If the depth of the liquid is d, then prove that the time taken by the body to reach the bottom of the liquid is [(2drho)/g(rho-delta)]^(1//2) second.

A liquid of density rho_0 is filled in a wide tank to a height h. A solid rod of length L, cross-section A and density rho is suspended freely in the tank. The lower end of the rod touches the base of the tank and h=L/n (where n gt 1). Then the angle of inclination theta of the rod with the horizontal in equilibrium position is

A liquid of density rho_0 is filled in a wide tank to a height h. A solid rod of length L, cross-section A and density rho is suspended freely in the tank. The lower end of the rod touches the base of the tank and h=L/n (where n gt 1). Then the angle of inclination theta of the rod with the horizontal in equilibrium position is