1 mole of `alpha`-tin at 1 atm and `13^@C` changes to 1 mole of `beta`-tin at 1 atm and `13^@C`. If the enthalpy of transition is `2090 J mol^(-1)`, calculate the entropy of transition.

The standard free energy change for a reaction is -213.3 KJ mol^(-1) "at" 25^(@)C . If the enthalpy change of the reaction is -217.77 KJ "mole"^(-1) . Calculate the magnitude of entropy change for the reaction in Joule "mole"^(-1)

Volume of 0.5 mole of a gas at 1 atm. pressure and 273^@C is

Volume of 1.5 mole of a gas at 1 atm. pressure and 273K is

A reaction is at equilibrium at 100^(@)C and the enthalpy change for the reaction is "42.6 kJ mol"^(-1) . What will be the value of DeltaS in "J K"^(-1)"mol"^(-1) ?

If the enthalpy change for the transition of liquid water to steam is 30 kJ mol^(-1)" at " 27^@C the entropy change for the process would be

If the enthalpy change for the transition of liquid water to steam is 300kJ mol^(-1)" at "27^(@)C , the entropy change for the proces would be

The internal energy change for the vapourisation of one mole water at 1 atm and 100°C will be (Enthalpy of vapourization of water is 40.66 kJ

Zinc reacts with dilute hydrochloric acid to give hydrogen at 17^(@)C . The enthalpy of the reaction is -12.00 kJ mol^(-1) of zinc and entropy change equals 50 J K^(-1) mol^(-1) for the reaction. Calculate the free enegry change and predict whether the reaction is spontaneous or not.

Two moles of an ideal gas at 1 atm are compressed to 2 atm at 273 K. The enthalpy change for the process is

Calculate the entropy change accompanying the conversion of 1 mole of ice at 273.1 K and 1 atm pressure into steam at 373.1 K and 1 atm pressure. At 273.1 K, the molar heat of fusion of ice, DeltaH_(f) is 6.00 kJ mol^(-1) and at 373.1 K, the molar heat of vapourization of water, DeltaH_(v) , is 40.6 kJ mol^(-1) . Also assume that the molar heat capacities, C_(p) , in the temperature range 373.1 to 273.1 K remains constant. Given that C_(p) = 75.25 m mol^(-1)K^(-1) and log 13.66 = 1.1354.