A given mass of gas expands from state A to state B by three paths 1, 2 and 3 as shown in the figure

If `w_(1), w_(2) and w_(3)` respectively are be the works done by the gas along three paths, then

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

A given mass of a 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 the three paths then

A given mass of gas expends 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 magnitude of worl done by the gas along three paths then :

A givne mass of a gas expands from a state A to the state B by three paths 1, 2 and 3 as shown in T-V indicator diagram. If W_(1),W_(2) and W_(3) respectively be the work done by the gas along the three paths, then

An ideal gas of mass m in a state A goes to another state B via three different processes as shown in Fig. If Q_(1), Q_(2) and Q_(3) denote the heat absorbed by the gas along the three paths, then

A gravitational field is present in a region. A point mass is shifted from A to B , along different paths shown in the figure. If W_1, W_2 and W_3 represent the work done by gravitational force for respective paths, then

A gas of given mass, is brought from stage A to B along three paths 1, 2 and 3, as shown in the figure. If the amount of work done in these three processes is respectively equal to W_(1), W_(2) and W_(3) , then–

An ideal gas is taken from state 1 to state 2 through optional path A, B, C and D as shown in the PV diagram. Let Q, W and U represent the heat supplied, work done and change in internal energy of the gas respectively. Then,