A given mass of gas expands from the state A to the state B by three paths 1,2 and 3 as shown in the figure. If `w_(1), w_(2) and w_(3)` respectively be the work done by the gas along three paths then:

An ideal gas goes from the state I to to the state f as shown in figure. The work done by the gas during the process

n moles of a gas expands from volume V_(1) to V_(2) at constant temperature T. The work done by the gas is

An ideal gas is taken from the state. A (pressure p, volume V) to the state B (pressure p/2, volume 2V) along a straight line path in the p-V diagram. (T - True & F - False) S_1 : The work done by the gas in the gas in process A to B exceeds the work that would be done by it if the system were taken from A to B along the isotherm. S_2 : In going from A to B, the temperature T of the gas first increases to a maximum value and then decreases. S_3 : Work done by the gas is negative as pressure is decreasing.

Three moles of an ideal monotomic gas performs a cycle ABCDA as shown in the figure The temperatures of the gas at the states A,B,C and D are 400 K , 800 k 2400 k and 1200 k respecitvely the work done by the gas during this cycle is R is universal gas constant

A gas expands from 1 litre to 3 litres at atmospheric pressure. The work done by the gas is about

One mole of ideal gas goes through a process pV^3 = Constant , where p and V are pressure and volume, respectively. Let W be the work done by the gas as its temperature is increased by Delta T . The value of |W| is (R is the universal gas constant. )

A gas underoes change from state A to state B . In this process , the heat absorbed and work done by the gas is 5 J and 8J respectively . Now gas is brought back to A by another process during which 3 J of heat is evolved . In this reverse process of B to A