For the reaction `X_2O_4(l) to 2XO_2(g)`,`
`DeltaU = 2.1 kcal, DeltaS = 20 cal `K^-1` at 300k
Hence, `DeltaG` is

For the reaction, X_(2)O_(4)(l)to2XO_(2)(g),DeltaU=2.1 kcal, DeltaS=20cal*K^(-1) at 300K, hence, DeltaG is -

For the reaction X_2Y_4(l) to 2 XY_2(g) at 300 K the values of DeltaU and DeltaS are 2 kCal and 20 Cal K^-1 respectively. The value of DeltaG for the reaction is

For the reaction X_(2)Y_(4)(l) to 2XY(g) at 300K the values of DeltaU and DeltaS are 2kcal and 20cal*K^(-1) respectively. The value of DeltaG for the reaction is-

For the reaction , 2A(g)+B(g) to 2D(g),DeltaU^(0)=-10.5kJ and DeltaS^(0)=-44.1J*K^(-1) . Calculate DeltaG^(0) for the reaction and predict whether it may occur spontaneously.

For the reaction at 288 K A(g)+B(g) iff C(g) +D(g) , DeltaH^@ = - 29.8kcal and DeltaS^@ =- 100cal_/K . Find the value of equilibrium constant.

Calculate the DeltaG^0 for the reaction N_2(g) + O_2(g) * 2NO(g) Given DeltaH^0 =180.5 K.J , and DeltaS^0 = 15 J at 25^@C .

In the reaction N_(2(g)) + O_(2(g)) to 2NO_((g)), DeltaH^@ reaction is + 179.9 kJmol^(-1) and DeltaS_("reaction")^@ = 66.09 JK^(-1)mol^(-1) . Calculate DeltaG^@ reaction at 300K.

For the reaction, SO_2(g) + 1/2 O_2(g) iff SO_3(g) , the value of K_c is 1.7 xx 10^(12) at 300K. Calculate the equilibrium constants for the following reactions at 300K : 2SO_2(g) + O_2(g) iff 2SO_3(g) and SO_3(g) iff SO_2(g) + 1/2O_2(g)

For the reaction 2SO_2(g) + O_2 (g) iff 2SO_3 (g) at 300K, the value of DeltaG^@ is - 690.9R. The equilibrium constant value for the reaction at that temperature is (R is gas constant)

At 298K, for attainment of equilibrium of the reaction N_(2)O_(4)(g)hArr 2NO_(2)(g) , 5 mol of each of the constituents is taken. Due to this, total pressure of the mixture turns 20 atm. If DeltaG_(f)^(0)(N_(2)O_(4))=100kJ*mol^(-1) and DeltaG_(f)^(0)(NO_(2))=50K(J*mol^(-1)) then- (1) Give the value of DeltaG of the reaction? (2) In which direction will the reaction proceed more to attain equilibrium?