One mole of an ideal diatomic gas follows the cycle ABCDA as shown in the figure. P₁ = 1.0 atm and V₁-12.3 L. P₂ = 2.0 a

[answerhappygod]

One Mole Of An Ideal Diatomic Gas Follows The Cycle Abcda As Shown In The Figure P 1 0 Atm And V 12 3 L P 2 0 A 1 (110.25 KiB) Viewed 39 times

One mole of an ideal diatomic gas follows the cycle ABCDA as shown in the figure. P₁ = 1.0 atm and V₁-12.3 L. P₂ = 2.0 atm and V₂=24.6 L. The temperatures are TÃ= 150 K, TB = 300 K, Tc = 600 K, and TD = 300 K, respectively. R = 8:314 J/(mole K), 1 atm = 1.013 x 105 Pa, 1 L = 10-³ m³. Show the physics approach and all steps. 10 points P, atm B с | P₂ P₁ A 1 V₁ D I V₂ V, L

(a) During the change from A -> B: Calculate the work done, the change in internal energy, and the Q transferred between the system and the surroundings. Has the internal energy increased or decreased? Does heat enter or leave the system? (b) During the change from B -> C: Calculate the work done, the change in internal energy, and the Q transferred between the system and the surroundings. Has the internal energy increased or decreased? Does heat enter or leave the system? (c) During the change from C -> D: Calculate the work done, the change in internal energy, and the Q transferred between the system and the surroundings. Has the internal energy increased or decreased? Does heat enter or leave the system? (d) During the change from D -> A: Calculate the work done, the change in internal energy, and the Q transferred between the system and the surroundings. Has the internal energy increased or decreased? Does heat enter or leave the system? (e) Calculate the net work done over the cycle? (d) Determine the total heat entering the system. (f) Determine the efficiency of the cycle.