2 moles of a diatomic gas are enclosed in a cylinder piston arrangment. The area of cross section and mass of the piston are `1 cm^(2)` and 1 kg respectively. A heater is supplying heat to the gas very slowly. Find heat supplied (in joule) by the heater is the piston moves through a distance of 10 cm.
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Figure shows a cylindrical container containing oxyegn (gamma = 1.4) and closed by a 50 kg frictionless piston. The area of cross section is 100cm(2) , atmospheric pressure is 100 kPa +E2 and g is 10 m s^(-2) . The cylinder is slowly heated for some time. Find the amount of heat supplied to gas if the piston moves out through a distsnce of 20 cm. .

Find out bulk stress on the spherical object of radius 10//pi cm if area and mass of piston are 50 cm^(2) and 50 kg , respectively, for a cylinder filled with gas as shown in figure.

Two moles of an ideal monoatomic gas are contained in a vertical cylinder of cross sectional area A as shown in the figure. The piston is frictionless and has a mass m. At a certain instant a heater starts supplying heat to the gas at a constant rate q J//s . Find the steady velocity of the piston under isobaric condition. All the boundaries are thermally insulated.

In an arrangement similar to a hydraulic lift, the diameters of smaller and larger pistons are 1.0 cm and 3.0 cm respectively. What is the force exerted on the larger piston when a force of 10 N is applied to the smaller piston?

Three moles of an diatomic gas are in a closed rigid container at temperature T (in K). 1 mole of diatomic gas gets dissociated into atoms without appreciable change in temperature. Now heat is supplied to the gas and temperature becomes 2T. If the heat supplied to the gas is x(RT), find the value of x.

Two moles of a diatomic gas at 300K are enclosed in a cylinder as shown in figure. Piston is light. Find out the heat given if the gas is slowly heated to 400K in the following three cases. (i) Piston to free to move (ii) If piston does not move (iii) If piston is heavy and movable

Figure shows a liquid being pushed out of a tube by pressing a piston. The area of cross section of the piston is 1.0 cm^2 and that of the tube at the outlet is 20 mm^2 . If the piston is pushed at a speed of 2cms^-1 . What is the speed of the outgoing liquid?

A non conducting piston of mass m and area of cross section A is placed on a non conducting cylinder as shown in figure. Temperature, spring constant, height of the piston are given by T,K,h respectively. Initially spring is relaxed and piston is at rest. Find (a) Number of moles (b) Work done by gas to displane the piston by distance d when the gas is heated slowly. (c ) Find the final temperature

A smooth vertical tube having two different cross sections is open from both the ends but closed by two sliding pistions as shown in Fig. and tied with an inextensible string. One mole of an ideal gas is enclosed between the piston The difference in cross-sectional areas of the two pistons is given Delta S . The masses of piston are m_(1) and m_(2) for larger and smaller one, respectively. Find the temperature by which tube is raised so that the pistons will be displaced by a distance l. Take atmospheric pressure equal to P_(0)

A smooth vertical tube having two different cross sections is open from both the ends but closed by two sliding pistions as shown in Fig. and tied with an inextensible string. One mole of an ideal gas is enclosed between the piston The difference in cross-sectional areas of the two pistons is given Delta S . The masses of piston are m_(1) and m_(2) for larger and smaller one, respectively. Find the temperature by which tube is raised so that the pistons will be displaced by a distance l. Take atmospheric pressure equal to P_(0)