For the process `H_2O(i) to H_2O(g)` at `T = 100^@C` and 1 atmospere pressure, the correct choice is

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

If at normal pressure and 100^(@)C the changes in enthalpy and entropy for the process, H_(2)O(l)toH_(2)O(g), are DeltaH and DeltaS respectively, then DeltaH-DeltaU is-

Which of the following is true for a reaction H_2O (I) m H_2O (g) at 100^@C 1 atm Pressure :

Calculate the entropy change, at 0^@C for the process H_2O(s) rarr H_2O(I) . Given : At 0^@C , H_2O(s) rarr H_2O(g) , Delta H=51885 J. mol^-1 and H_2O(I) rarr H_2O(g) , Delta H=45860 J. mol^-1 .

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.

A 2L flask contains 0.4 g O_(2) and 0.6 g H_(2) at 100^(@)C . Calculate the total pressure of the gas mixture in the flask.

At 986^(@) C the value of equilibrium constant (K_c) for the reaction, CO(g)+H_2O(g)toCO_2(g)+H_2(g) is 0.63At this temperature, 1 mol of H_2O (g) is allowed to react with 3 mol of CO(g). This results in the above equilibrium in which the observed pressure is 2.0 atm. Find the number of moles of H_2 (g) produced at equilibrium and the partial pressure of each gas

The value of K_c = 4.24 at 800K for the reaction, CO(g) + H_2O(g) iff CO_2(g) + H_2 (g) Calculate equilibrium concentrations of CO_2, H_2, CO and H_2O at 800 K, if only CO and H_2O are present initially at concentrations of 0.10M each.

The equilibrium constant (K_P) for the decomposition of gaseous H_2O, H_2O(g)toH_2(g)+1/2O_2(g) , is related to degree of dissociation (prop) at a total pressure ( P) as-