One mole of a mono atomic gas of molar mass M undergoes a cyclic process as shown in the figure. Here `rho` is density and P is pressure of the gas.
(a) Calculate the heat rejected by the gas in one complete cycle.
(b) Find the efficiency of the cycle.

The density (rho) versus pressure (p) graph of one mole of an ideal monoatomic gas undergoing a cyclic process is shown in figure. Molecular mass of gas is M. (a) Find work done in each process. (b) Find heat rejected by gas in one complete cycle. (c) Find the efficiency of the cycle.

The density (rho) versus pressure (p) graph of one mole of an ideal monoatomic gas undergoing a cyclic process is shown in figure. Molecular mass of gas is M. (a) Find work done in each process. (b) Find heat rejected by gas in one complete cycle. (c) Find the efficiency of the cycle.

The pressure versus volume graph of one mole of an ideal monatomic gas undergoing a cyclic process is shown in figure. The molecular mass of the gas is M. (a) Find the work done in each process. (b) Find heat rejected by gas in one complete cycle. (c) Find the effiency of the cycle.

One mole of an ideal mono-atomic gas is taken round cyclic process ABCD as shown in figure below. Calculate

One mole of an ideal mono-atomic gas is taken round cyclic process ABC as shown in figure below. Calculate work done

One mole of an ideal mono-atomic gas is taken round cyclic process ABC as shown in figure below. Calculate work done

One mole of an ideal monoatomic gas undergoes a cyclic process as shown in figure. Then the change in the energy in expanding the gas from a to c along the path abc is:

Two moles of a monatomic ideal gas undergo a cyclic process ABCDA as shown in figure. BCD is a semicircle. Find the efficiency of the cycle.

Two moles of a monatomic ideal gas undergo a cyclic process ABCDA as shown in figure. BCD is a semicircle. Find the efficiency of the cycle.