Figure shows a cycle `ABCDA` undergone by `2` moles of an ideal diatomic gas. The curve `AB` is a rectangular hyperbola and `T_(1)=300K` and `T_(2)=500K`. Determine the work done by the gas in the process `ArarrB`.

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

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

3 moles of an ideal mono atomic gas performs a cycle as shown in fig. If gas temperature T_(A)=400 K T_(B)=800K,T_(C)=2400K , and T_(D)=1200K . Then total work done by gas is

3 moles of an ideal mono atomic gas performs a cycle as shown in fig. If gas temperature T_(A)=400 K T_(B)=800K,T_(C)=2400K , and T_(D)=1200K . Then total work done by gas is

3 moles of an ideal mono atomic gas performs a cycle as shown in fig. If gas temperature T_(A)=400 K T_(B)=800K,T_(C)=2400K , and T_(D)=1200K . Then total work done by gas is

Two moles of an ideal mono-atomic gas undergo a cyclic process as shown in the figure. The temperatures in different states are given as 6T_(1) = 3T_(2) = 2T_(4) = T_(3) = 1800 K . Determine the work done by the gas during the cycle.

Two moles of an ideal mono-atomic gas undergo a cyclic process as shown in the figure. The temperatures in different states are given as 6T_(1) = 3T_(2) = 2T_(4) = T_(3) = 1800 K . Determine the work done by the gas during the cycle.

One mole of an ideal monoatomic gas undergoes a cyclic process as shown in figure . Temperature at point 1 = 300K and process 2-3 is isothermal . . Net work done by gas in complete cycle is

One mole of an ideal monoatomic gas undergoes a cyclic process as shown in figure . Temperature at point 1 = 300K and process 2-3 is isothermal . . Net work done by gas in complete cycle is