One mole of helium gas follows the cycle 1-2-3-1 shown in the diagram. During process 3-1, the internal energy (U) of the gas depends on its volume (V) as `U=bV^(2)`, where b is a positive constant. If gas releases the amount of heat `Q_(1)` during process 3-1 and gas absorbs th amount of heat `Q_(2)` during process `1rarr2rarr3` them:

`(V_(3))/(V_(1))` is

One mole of helium gas follows the cycle 1-2-3-1 shown in the diagram. During process 3-1, the internal energy (U) of the gas depends on its volume (V) as U=bV^(2) , where b is a positive constant. If gas releases the amount of heat Q_(1) during process 3-1 and gas absorbs th amount of heat Q_(2) during process 1rarr2rarr3 them: The value of O_(1)//Q_(2) is

One mole of helium gas follow cycle 1-2-3-1 shown in the diagram. During process 3-1 , the internal energy (U) of the gas depends on its volume (V) as U=bV^(2) , where b is a positive constant. If gas releases the amount of heat Q during process 3-1 and gas absorbs the amount of heat Q_(2) during process 1rarr2rarr3 . The value of ratio of volume of gas in state -3(V_(3)) to that of gas in state -1(V_(1)) is:

The temperature (T) of one mole of an ideal gas varies with its volume (V) as T= - alpha V^(3) + beta V^(2) , where alpha and beta are positive constants. The maximum pressure of gas during this process is

Two moles of an ideal monoatomic gas is taken through a cycle ABCA as shown in the p - T diagram. During the process AB, the pressure and temperature of the gas vary such that pT = constant. If T_(1)= 300 K and the amount of heat released by the gas during the process AB is Q = -x R , then the value of x is

Two moles of an ideal gas are undergone a cyclic process 1-2-3-1. If net heat exchange in the process is 300J, the work done by the gas in the process 2-3 is

The internal energy of a gas is given by U = 3 pV. It expands from V_(0) to 2V_(0) against a constant pressure p_(0) . The heat absorbed by the gas in the process is

One mole of an ideal gas at initial temperature T, undergoes a quasi-static process during which the volume V is doubled. During the process the internal energy U obeys the equation U=aV(3) where a is a constant. The work done during this process is-

One mole of a monoatomic ideal gas is expanded by a process described by PV^(3) = C where C is a constant. The heat capacity of the gas during the process is given by (R is the gas constant)

The P - V diagram of 2 gm of helium gas for a certain process A rarr B is shown in the figure. What is the heat given to the gas during the process A rarr B ?

An ideal monoactomic gas undergoes a process ini which its internal energy depends upon its volume as U=asqrt(V) [where a is a constant] (a) find work done by a gas and heat transferred to gas to increse its internal energy by 200 J. (b) find molar specific heat of gas for this process.