Consider the barometer shown in figure. Density of mercury is `rho`. A small hole is made at point S as shown. The mercury come out from this hole with speed `v` equal to

Consider the barometer shown in figure. If a small hole is made at a point P in the barometer tube, will the mercury come out from this hole?

An open vessel full of water is falling freely under gravity. There is a small hole in one face of the vessel, was shown in te figure. The water which comes out from the hole at the instant when hole is at height H above the ground strikes the ground at a distance of x from P. Which of the followin is correct for the situation described? (a). The value of x is 2sqrt((2hH)/(3)) (b). The value of x is sqrt((4hH)/(3)) (c). The value ofx can't be computed from information providec. (d). The question is irrevalent as no water comes out from the hole.

A container of cross-section area 'S' and height 'h' is filled with mercury up to the brim. Then the container is sealed airtight and a hole of small cross section area 'S//n' (where 'n' is a positive constant) is puched in its bottom. Find out the time interval upto which the mercury will come out from the bottom hole. [Take the atmospheric pressure to be equal to h_(0) height of mercury column: h gt h_(0) ]

Consider the circuit shown in the figure. Find the current in branch AO and OC . Potential of point A = 10 V of point B = 20 V and of C = 30 V.

A container filled with liquid up to height h is placed on a smooth horizontal surface. The container is having a small hole at the bottom. As the liquid comes out from the hole, the container moves in a backward direction with acceleration a and finally, when all the liquid is drained out, it acquires a velocity v . Neglect mass of the container. In this case

An infinite nonconducting sheet has surface charge density s. There is a small hole in the sheet as shown in the figure. A uniform rod of length l having linear charge density lambda is hinged in the hole as shown. If the mass of the rod is m, then the time period of oscillation for small angular displacement is

A rectangular tank of height 10m filled with water, is placed near the bottom of a plane inclined at an angle 30^(@) with horizontal. At height h form bottom a small hole is made (as shown in figure) such that the stream coming out from hole, strikes the inclined plane normally. Calculate h.

A ray of light, travelling parallel to diameter of a sphere enters the sphere through a hole at point A as shown in the figure. The inner surface of the sphere is made perfectly reflecting. Find the number of reflections suffered by the ray before coming out of the sphere.

Water is filled to height h in a fixed vertical cylinder placed on horizontal surface. At time t = 0 a small hole a drilled at a height h//4 from bottom of cylinder as shown. The cross section area of hole is a and the cross-section area of cylinder is A such that A gtgt a . Let the value of horizontal distance of point where the4 water fall on horizontal surface from bottom of cylinder be x as shown. Then from time t = 0 till water comes out of hole, pick the correct statement:

Water is filled to height h in a fixed vertical cylinder placed on horizontal surface. At time t = 0 a small hole a drilled at a height h//4 from bottom of cylinder as shown. The cross section area of hole is a and the cross-section area of cylinder is A such that A gtgt a . Let the value of horizontal distance of point where the4 water fall on horizontal surface from bottom of cylinder be x as shown. Then from time t = 0 till water comes out of hole, pick the correct statement: