The molar heat capacity `(C_(P))` of `CD_(2)O` is 10 cals at 1000 K. The change in entropy associated with cooling of 32 g of `CD_(2)O` vapour form 1000 K to 100 K at constant pressure will be : (D= deuterium, at mass =2u)

Molar heat capacity of CD_(2)O (deuterated form of formaldehyde) at constant pressure in 9 cal mol^(-1) K^(-1) at 1000K . Calculate the entropy change associated with cooling of 3.2 g of CD_(2)O vapour from 1000 to 900K .

When two moles of an ideal gas (C_(p.m.)=(5)/(2)R) heated form 300K to 600K at constant pressure, the change in entropy of gas (DeltaS) is:

The entropy change for cooling 1.6 g of an organic compound (mol. Wt. 32, molar heat capacity at constant pressure, 59 JK^(-) mol^(-) ) from 1000 K to 800 K is :

The molar heat capacity of a gas at constant volume is found to be 5 cal mol^(-1) K^(-1) . Find the ratio gamma = C_p/C_v for the gas. The gas constant R=2 cal mol^(-1) K^(-1).

ii. One mole of N_(2)O_(4)(g) at 100 K is kept in a closed container at 1.0 atm pressure. It is heated to 300 K , where 30% by mass of N_(2)O_(4)(g) decomposes to NO_(2)(g) . The resultant pressure will be

One "mole" of N_(2)O_(4)(g) at 100 K is kept in a closed container at 1.0 atm pressure. It is heated to 400 K , where 30% by mass of N_(2)O_(4)(g) decomposes to NO_(2)(g) . The resultant pressure will be

The standard enthaply for the reaction H_(2)(g) + 1//2 O_(2)(g) to H_(2)O(l) is - 285.76 kJ at 298 K. Calculate the value of DeltaH at 373 K .The molar heat capcities at constant pressure (C_(P)) in the given temperature range of H_(2)(g),O_(2)(g) and H_(2)O(l) are respectively 38.83,16 and 75.312 JK^(-1) mol^(-1) .

For a reaction 2A(g)+2B(g) rarr 2C(g)+D(g) . If heat of reaction at constant pressure is -28 K.cal. The heat of reaction at constant volume at 27^(@)C is