Assume constant temperature if the tube is changed to vertical position and the pallet comes down by 5 cm then find out `P_(0) `

Two arms of a U-tube have unequal diameters d_(1) = 1.0 mm and d_(2) = 1.0 cm . If water (surface tension 7xx10^(-2)N//m ) is poured into the tube held in the vertical position, find the difference of level of water in the U-tube . Assume the angle of contact to be zero.

If above tube is held vertical with open end upward then find the length of air column (in cm).

At constant temperature, if vol. of gas decrease by 5% then what will be to change in pressure.

There is a long vertical tube of radius r containing air at atmospheric pressure. A steel ball is held at the mouth of the tube and dropped. The ball has radius r and it just fits inside the tube. The tube wall is perfectly smooth and no air can leak from the tube as the ball falls inside it. The ball falls through half the length of the tube before coming to rest. Assume that wall of the tube is perfectly conducting and temperature of the air inside the tube remains constant. Density of steel is d and atmospheric pressure is P_(0) and take L gt gt r . Take air to be an ideal gas. (a) Find the radius (r) of the tube. (b) At what depth from the top of the tube the ball will be in equilibrium?

A narrow tube of length l and radius r is sealed at one end. Its open end is brought in contact with the surface of water while the tube is held vertical. The water rises to a height h in the tube. The contact angle of water with the tube wall is theta , density of water is rho and the atmospheric pressure is P_(o) . Find the surface tension of the liquid. Assume that the temperature of air inside the tube remains constant and the volume of the meniscus is negligible.

One end of an insulating U tube is sealed using insulating material. A mono atomic gas at temperature 300 K occupies 20 cm length of the tube as shown. The level of mercury on two sides of the tube differ by 5 cm. The other end of the tube is open to atmosphere. Area of cross section of the tube is uniform and is equal to 0.01 m^(2) . The gas in the tube is heated by an electric heater so as to raise its temperature to 562.5 K. Assume that no heat is conducted to mercury by the gas. (a) Find the final length of the gas column. (b) Find the amount of heat supplied by the heater to the gas.

Water rises to a height of 5 cm when a narrow glass tube is dipped vertically in it . If the tube is inclined at 60^(@) to the vertical , then the rise of water in the capillary tube will be

Two vertical cylinders are connected by a small tube at the bottom. It contains a gas at constant temperature . Initially the pistons are located at the same height. The diameters of the two cylinders are different . Outside the cylinder the space is vaccum . Gravitational acceleration is h,h_(0) = 20cm , m_(1) = 2kg "and" m_(2) =1kg . The pistons are initially in equilibrium. If the masses of the piston are interchanged find the separation between the two pistons when they are again in equilibrium. Assume constant temperature .

Figure shows an ideal gas. Its pressure, volume and temperature are P_0, V_0 and T_0 respectively. Thin U-tube contains mercury. It is seen that when 20 cm of extra mercury is added in limb B of U-tube and temperature of gas is doubled, level of A is maintained at its position. Consider surrounding to be vacuum. Find the initial pressure of gas (in cm of Hg.)