One mole of a monoatomic ideal gas is taken through the cycle ABCDA as shown in the figure.
`T_A=1000K` and `2p_A=3p_B=6p_C`

`[Ass um e(2/3)^0.4=0.85` and `R=(25)/(3)JK^-1mol^-1]`
The temperature at B is

One mole of a monoatomic ideal gas is taken through the cycle ABCDA as shown in the figure. T_A=1000K and 2p_A=3p_B=6p_C [Ass um e(2/3)^0.4=0.85 and R=(25)/(3)JK^-1mol^-1] Work done by the gas in the process ArarrB is

One mole of a monoatomic ideal gas is taken through the cycle ABCDA as shown in the figure. T_A=1000K and 2p_A=3p_B=6p_C [Ass um e(2/3)^0.4=0.85 and R=(25)/(3)JK^-1mol^-1] Heat lost by the gas in the process BrarrC is

One mole of a monoatomic ideal gas is taken through the cycle ABCDA as shown in the figure. T_A=1000K and 2p_A=3p_B=6p_C [Ass um e(2/3)^0.4=0.85 and R=(25)/(3)JK^-1mol^-1] Work done by the gas in the process ArarrB is

One mole of a monoatomic ideal gas is taken through the cycle ABCDA as shown in the figure. [Ass um e(2/3)^0.4=0.85 and R=(25)/(3)JK^-1mol^-1] The temperature at B is T_A=1000K and 2p_A=3p_B=6p_C

One mole of a monoatomic ideal gas is taken through the cycle shown in figure The pressure and temperature at A, B etc are denoted by P_A,P_B - , T_A, T_B - , etc respectively A to B adiabatic expansion B to C cooling at constant volume C to D adiabatic compression D to A heating at constant volume Given that : T_A =1000 K, P_B=2/3P_A and P_C=1/3P_A the heat lost by the gas in process B to C

One mole of a monoatomic ideal gas is taken through the cycle shown in figure The pressure and temperature at A, B etc are denoted by P_A,P_B , T_A, T_B - , etc respectively A to B adiabatic expansion B to C cooling at constant volume C to D adiabatic compression D to A heating at constant volume Given that : T_A =1000 K, P_B=2/3P_A and P_C=1/3P_A the work done by the gas in process A to B

One mole of a monatomic ideal gas is taken through the cycle shown in the figure: A to B adiabatic expansion B to C: cooling at constant volume C to D adiabatic compression D to C: heating at constant volume. The pressure and temperature at P_A, P_B etc. T_A , T_B etc. are denoted etc. respectively. Given that T_A = 1000 K, P_B =(2 //3)P_A and P_C = (1 //3)P_A Calculate the following quantities. The work done by the gas in process A to B (in J)

One mole of a monatomic ideal gas is taken through the cycle shown in the figure: A to B adiabatic expansion B to C: cooling at constant volume C to D adiabatic compression D to C: heating at constant volume. The pressure and temperature at P_A, P_B etc. T_A , T_B etc. are denoted etc. respectively. Given that T_A = 1000 K, P_B =(2 //3)P_A and P_C = (t //3)P_A Calculate the following quantities. The heat lost by the gas in process B to C (in J)

One mole of a monatomic ideal gas is taken through the cycle shown in the figure: A to B adiabatic expansion B to C: cooling at constant volume C to D adiabatic compression D to A: heating at constant volume. The pressure and temperature at P_A, P_B etc. T_A , T_B etc. are denoted etc. respectively. Given that T_A = 1000 K, P_B =(2 //3)P_A and P_C = (1 //3)P_A Calculate the following quantities. The temperature T_D (in K) [Given : (2/5)^(2//5) = 0.85 ]

One mole of ideal gas (C_(P, m) = 15 JK^(-1) "mole"^(-1)) follow the process as shown in figure.