`DeltaH` for the reaction at 298 K `CO(g)+1//2O_(2)(g)` is `282.85 KJ mol^(-1)`. Calculate `DeltaU` of the reaction.

The value of DeltaH for the given reaction at 298K is -282.85 kJ*mol^(-1) . Calculate the change in intenral energy: CO(g)+(1)/(2)O_(2)(g) to CO_(2)(g) .

The activation energy for the reaction, 2 HI (g) to +I-2(g), is 209.5 KJ mol _-1 at 581K, Calculate the fraction of molecules of reactants having energy equal to or greater than activation energy.

At 25^(@)C , Delta H^(0) for the reaction , N_(2)(g)+(1)/(2)O_(2)(g) to N_(2)O(g) , is +82 kJ . At this temperature if the standard molar entropies for N_(2)(g),O_(2)(g) and N_(2)O(g) are 191.6, 205.2 and 219.9 J. K^(-1). " mol"^(-1) respectively, calculate Delta S_("univ")^(0) for the reaction.

At 1 atm and 298K DeltaH^(0) value of the reaction 2H_(2)(g)+O_(2)(g)to2H_(2)O(l) is -572 kJ. Calculate the change in entropy of the system and surroundings for this reaction. Is this reaction spontaneous at that temperature and pressure? Given: Standard molar entropies of H_(2)(g),O_(2)(g)&H_(2)O(l) at 298K are 130.6, 205.0 and 69.90 J*K^(-1)*mol^(-1) respectively.

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.

DeltaH^@ & DeltaS^@ for the reaction H_2 (g) + I_2 (g) = 2 HI (g) are 16.23 Kj mol^-1 and 63.8 kj mol^-1 predic whether the reaction be spontaneous at 35^@C .

The standard enthalpy of formation of H_2O(g) at 298 K is -241.82 kJ mol^-1 , Calculate DeltaH^@ at 373 K. Assume that C_p , is independent of temperature C "_p^o of H_2O(g) = 33.58 JK^-1 mol^-1 C "_p^o of H_2(g) = 28.84 JK^-1 mol^-1 C "_p^o of O_2(g) = 29.37 JK^-1 mol^-1

Calculate Delta H-DeltaU at 25^@C for the reaction: H_2(g)+( 1/2)O_2(g) = H_2O(l) .