An ideal monatomic gas is confined in a horizontal cylinder by a spring loaded piston (as shown in the figure). Initially the gas is at temperature `T_(1)`, pressure `P_(1)` and volume `V_(1)` and the spring is in its relaxed state. The gas is then heated very slowly to temperature `T_(2)`, pressure `P_(2)` and volume `V_(2)`. During this process the piston moves out by a distance `x`. lgnoring the friction between the piston and the cylinder, the correct statement (s) is (are)

We will assume that the gas on the side of container having spring is connected to atmosphere. Hence, its pressure remains constant at `P_1`.
In final position of Piston, force balance gives :`Kx + P_1 A = P_2 A`
Where A = cross sectional area of piston
So, `Kx = (P_2 - P_1)A" ...(1)"`
Also, `(P_1 V_1)/T_1 = (P_2 V_2)/T_2`
If `V_2 = 2V_1 ,T_2 = 3T_1,` Then `pP_2 = 3/2 P_1`
Also, `V_2 - V_1 = Ax" ...(ii)"`
(i) and (ii) give : `Kx = (P_2 - P_1) ((V_2 - V_1))/x`
`:." "1/2 Kx^2 = 1/2 (P_2 - P_1) ((V_2 -V_1))" ....(iii)"`
`= 1/2 (P_1/2) (V_1) = (P_1V_1)/4` Hence, (A) is correct.
`Delta U = f/2 (P_2 V_2 - P_1 V_1)" "=3/2[3/2 xx2 P_1 V_2 - P_1 V_1]= 3 P_1 V_1`
Hence, (B) is correct as well.
Net work done on piston by all forces is zero. So, `W_("gas") = 1/2 Kx^2 - P_1 (V_2 - V_1) =0`
`:." "W_("gas") = (P_1 V_1)/3 + 2 P_2 V_1" "W_("gas") = 7/3 P_1 V_1`
So, (C) also turns out to be correct.
` Q = Delta U + W`
`Delta U = 3/2 (P_2 V_2 - P_1 V_1)=3/2 (4/3 P_1 * 3V_1 - P_1 V_1 )" "rArr" "Delta U = 9/2 P_1 V_1`
`:." Q" = 9/2 P_1 V_1 + 7/3 P_1 V_1 " "rArr" "Q = 41/6 P_1 V_1`