On combustion `C_(x)H_(y)(l)` forms `CO_(2)(g) and H_(2)O(l)`. At a given temperature and pressure, the value of `((DeltaH-DeltaU)/(RT))` in this combustion reaction is-

Given: C_(3)H_(8)(g)+5O_(2)(g)to3CO_(2)(g)+4H_(2)O(l) and C_(3)H_(8)(g)+5O_(2)(g)to3CO_(2)(g)+4H_(2)O(g) . At a fixed temperature and pressure between these two reactions the heat evolved in the second reaction is _____ than that in the first one.

What will be the difference between DeltaH and DeltaU in the combustion reaction of C_(10)H_(8)(g) at 25^(@)C ?

The heat of reaction for the following reaction (DeltaH^(0)) at 25^(@)C temperatue is -1368 kJ: C_(2)H_(5)OH(l)+3O_(2)(g) to 2CO_(2)(g)+3H_(2)O(l) If the enthalpy of formation of CO_(2)(g) and H_(2)O(l) at 25^(@)C are -393.5 and -285.8 kJ*mol^(-1) respectively, then what will be the value of the standard enthalpy of formation of C_(2)H_(5)OH(l) ?

At 25^(@)C and 1 atm, heat of formation of C_(2)H_(4) (g), CO_(2)(g) and H_(2)O(l) are 52 " kJ mol"^(-1), -394 " kJ mol"^(-1) and -286 " kJ mol"^(-1) respectively. Calculate the heat of combustion of C_(2)H_(4)(g) .

The standard enthalpy of combustion of C_(x)H_(y)(l) at 25^(@)C is Q kJ*mol^(-1) . Write down the thermochemical equation for the combustion reaction of this compound.

The combustion of benzene (l) gives CO_(2) (g) and H_(2)O (l) . Given that heat of combustion of benzene at constant volume is -3263.9 kJ * mol^(-1) at 25^(@) C , heat of combustion ( in kJ * mol^(-1)) of benzene at constant pressure will be - (R = 8.314 J * K^(-1) * mol^(-1) )

Given, C(graphite)+ O_(2)(g)toCO_(2)(g),Delta_(r)H^(0)=-393.5kJ*mol^(-1) H_(2)(g)+(1)/(2)(g)toH_(2)O(l),Delta_(r)H^(0)=-285.8kJ*mol^(-1) CO_(2)(g)+2H_(2)O(l)toCH_(4)(g)+2O_(2)(g),Delta_(r)DeltaH^(0)=+890.3kJ*mol^(-1) Based on the above thermochemical equations, the value of Delta_(r)H^(0) at 298K for the reaction, C(graphite) +2H_(2)(g)toCH_(4)(g) , will be-

For the reaction H_2O(s) iff H_2O(l) at 0^@C and normal pressure

At 986^(@)C , 3 mol of H_(2)O(g) and 1 mol of CO(g) react with each other according to the reaction, CO(g)+H_(2)O(g)hArr CO_(2)(g)+H_(2)(g) . At equilibrium, the total pressure of the reaction mixture is found to be 2.0 atm. If K_(c)=0.63 (at 986^(@)C ), then at equilibrium find (1) the number of moles of H_(2)(g) , (2) the partial pressure of each of the gases.