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, 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_2O_4(l) to 2XO_2(g) , DeltaU = 2.1 kcal, DeltaS = 20 cal K^-1 at 300k Hence, DeltaG is

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 1/2N_(2(g)) + 3/2 H_(2(g)) to NH_(3(g)) . The standard entropies of N_(2(g)), H_(2(g)) and NH_(3(g)) are 191.6,130.5 and 192.5 JK^(-1) "mol"^(-1) respectivly. If free energy charge of the reaction is -16.67 kJ. Calculate the Delta H_("reaction")^@ for the formation of NH_3 at 298 K.

For the reaction, CaCO_(3)(s)toCaO(s)+CO_(2)(g),DeltaH^(0)=+179.1kJ*mol^(-1) and DeltaS^(0)=160.2J*K^(-1) . If DeltaH^(0) and DeltaS^(0) are temperature independent, then temperature above which the reaction will be spontaneous is equal to-

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 2A(g) + B(g) to 2D(g), triangleU^@ = -10.5kJ and triangleS^@ = -44.1 JK^-1 Calculate triangleG^@ for the reaction, and predict whetehr the reaction may occur spontaneously. ( R = 8.314 xx 10^-3 kJ K^-1 mol^-1, T = 298 K )

Given that (at 25^(@)C) : (1)/(2)H_(2)(g)+(1)/(2)O_(2)(g) to OH(g), Delta H^(0)= 38.95 " kJ mol"^(-1) H_(2)(g)+(1)/(2)O_(2)(g) to H_(2)O (g), Delta H^(0) = -241.8 " kJ mol"^(-1) H_(2)(g) to 2H(g), Delta H^(0)= 436.0 " kJ mol"^(-1) O_(2)(g) to 2O (g), Delta H^(0)= 498.3 " kJ mol"^(-1) Calculate Delta H^(0) for the following reaction - (a) OH(g) to H(g)+O(g) (b) H_(2)O(g) to 2H(g)+O(g)

DeltaH value for the given reactions at 25^(@)C are- C_(3)H_(8)(g)to3C(s)+4H_(2)(g),DeltaH^(0)=103.8kJ*mol^(-1) 2H_(2)(g)+O_(2)(g) to 2H_(2)O(l),DeltaH^(0)=-571.6kJ*mol^(-1) C_(2)H_(6)(g)+(7)/(2)O_(2)(g)to2CO_(2)(g)+3H_(2)O(l),DeltaH^(0)=-1560kJ*mol^(-1) CH_(4)(g)+2O_(2)(g) to CO_(2)(g)+2H_(2)O(l),DeltaH^(0)=-890kJ*mol^(-1) C(s)+O_(2)(g) to CO_(2)(g),DeltaH^(0)=-393.5kJ*mol^(-1) Calculate DeltaH^(0) for the reaction at 25^(@)C C_(3)H_(8)(g)+H_(2)(g)toC_(2)H_(6)(g)+CH_(4)(g)

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)