Shows a cylindrical tube with adiabatic walls and fittled with a diathermic separetor. The separetor can be slid in the tube by and external mechanism. An ideal gas is injected into the two sides at equal pressures and equal temperatures. The separetor remaons in equilibrium at the middle. It is now slid to pisition where it devides the tube in the ratio of 1:3. Find the ratio of the pressures in the two parts of the vessel.

Figure shows a cylindridcal tube with a adibatic walls and fitted with an adiabatic separtor. The separator can be slid into the tube by an external mechanism. An ideal gas (gamma=1.5) is injected in the two sides at equal pressures and temperatures . The separator remains in equilibrium at the middel. It is now slid to a position where it divides the tube in the ratio 1:3 Find the ratio of the tempertures in the two parts of the vessel.

An adiabatic cylindrical tube is fitted with an adiabatic separator as shown in figure. Initial separator is in equilibrium and divides a tube in two equal parts. The seperator can be slide into the tube by an extermal mechanism. An ideal gas (gamma = 1.5) is injected in the two slides at equal pressure and temperature. Now separator is slid to a piston where it divides the tube in the ratio 7 :3 The ratio of the temperature in the two parts of the vessel is sqrt(n) : sqrt(7) find n .

What is the difference between an adiabatic wall and a diathermic wall?

In the sieve tubes pressure gradient is maintained with the help of

For an adiabatic expansion of an ideal gas the fractional change in its pressure is equal to

Why is a cathode ray tube evacuated to a low pressure ?

Fig shows a cylindrical tube of volume V with adiabatic walls containing an ideal gas. The internal energy of this ideal gas is given by 1.5nRT. The tube is divided into two equal parts by a fixed diathermic wall. Initially, the pressure and the temperature are p_(1), T_(1) on the left and p_(2), T_(2) on the right. the system is left for sufficient time so that the temperature becomes equal on the two sides. (a) how much work has been done by the gas on the left part ? (b) find the final pressures on the two sides. (c ) find the final equilibrium temperature. (d) how much heat has flown from the gas on the right to the gas on the left ?

Figure shows an adiabatic cylindrical tube of volume (V_0) divided in two parts by a frictionless adiabatic separator . Initially, the separator is kept in the middle, an ideal gas at pressure (P_1) and the temperatures (T_1) is injected into the left part and the another ideal gas at pressures (P_2) and temperature (T_2) is injected into the right part. (C_p / C_v = gamma) is the same for both the gases. The separator is slid slowly and is released at a position where it can stay in equilibrium. Find (a) the volumes of the parts, (b) the heat given to the gas in the left part and (c) the final common pressure of the gases.

An ideal gas undergoing adiabatic change has the following pressure-temperature relationship

Water enters into a smooth horizontal tapering tube with a speed 2 m/sec and emerges out of the tube with a speed 8 m/sec . Find the ratio of the radii of cross sections of the tube at these two ends.