Calculate `DeltaG^(Theta)` for the conversion of oxygen to ozone, `((3)/(2)) O_(2)(g) hArr O_(3)(g) at 298 K`, of `K_(p)` for this conversion is `2.47 xx 10^(-29)`.

Calculate G° for conversion of oxygen to ozone 3/2 O2 ⇌ O3(g) at 298 Kp, if K for this conversion is 2.47 x 10-29 in standard pressure units.

For the reaction CO(g)+(1)/(2) O_(2)(g) hArr CO_(2)(g),K_(p)//K_(c) is

K_(p)//K_(c) for the reaction CO(g)+1/2 O_(2)(g) hArr CO_(2)(g) is

K_(p)//K_(c) for the reaction CO(g)+1/2 O_(2)(g) hArr CO_(2)(g) is

What is DeltaG^(ɵ) for the following reaction? 1/2 N_(2)(g)+3/2 H_(2)(g) hArr NH_(3)(g), K_(p)=4.42xx10^(4) at 25^(@)C

What is DeltaG^(ɵ) for the following reaction? 1/2 N_(2)(g)+3/2 H_(2)(g) hArr NH_(3)(g), K_(p)=4.42xx10^(4) at 25^(@)C

Calculate DeltaG^(Theta) for the following reaction at 298K: CO(g) +((1)/(2))O_(2)(g) rarr CO_(2)(g), DeltaH^(Theta) =- 282.84 kJ Given, S_(CO_(2))^(Theta)=213.8 J K^(-1) mol^(-1), S_(CO(g))^(Theta)= 197.9 J K^(-1) mol^(-1), S_(O_(2))^(Theta)=205.0 J K^(-1)mol^(-1) ,

The standard Gibbs energy change for the conversion of oxygen to ozone at 300 K is [Given that K_p for the change (3/2)O_2(g) hArr O_3(g) at 300 K is 2.5xx10^-30 and log_(10)5=0.699 ]

For the equilibrium H_(2) O (1) hArr H_(2) O (g) at 1 atm 298 K

K_(C) " for " H_(2) (g)+ 1//2 O_(2)(g) rArr H_(2) O (l)at 500 K is 2.4 xx 10^(47), K_(p) of the reaction is .