Calculate the entropy change accompanying the following change of state
`5 mol` of `O_(2) (27^(@)C, 1 atm) rarr 5 mol of O_(2) (117^(@)C, 5 atm)`
`C_(P)` for `O_(2) = 5.95 cal deg^(-1) mol^(-1)`

Calculate the entropy change accompanying the following change of state H_(2)O (s, -10^(@)C, 1 atm) rarr H_(2)O(l, 10^(@)C, 1atm) C_(P) for ice = 9 cal deg^(-1) mol^(-1) C_(P) for H_(2)O = 18 cal deg^(-1) mol^(-1) Latent heat of fustion of ice = 1440 cal mol^(-1) at 0^(@)C .

Calculate the entropy change accompanying the following change of state H_(2)O (s, 10^(@)C, 1 atm) rarr H_(2)O(l, 10^(@)C, 1atm) C_(P) for ice = 9 cla deg^(-1) mol^(-1) C_(P) for H_(2)O = 18 cal deg^(-1) mol^(-1) Latent heat of fustion of ice = 1440 cal mol^(-1) at 0^(@)C .

Calculate the entropy change accompanying the following change of state H_(2)O (s, 10^(@)C, 1 atm) rarr H_(2)O(l, 10^(@)C, 1atm) C_(P) for ice = 9 cla deg^(-1) mol^(-1) C_(P) for H_(2)O = 18 cal deg^(-1) mol^(-1) Latent heat of fustion of ice = 1440 cal mol^(-1) at 0^(@)C .

The entropy change of x_(2) gas, during the following irreversible process, approximately is how much? x_(2) gas ( 27^(@)C , 1 atm, 5 moles ) rarr x_(2) gas ( 117^(@)C , 5 atm, 5 moles) ( C_(P) of x_(2) = 6.95 cal/mol/ ""^(@)C ), log 1.3= 0.1139

The entropy change of x_(2) gas, during the following irreversible process, approximately is how much? x_(2) gas ( 27^(@)C , 1 atm, 5 moles ) rarr x_(2) gas ( 117^(@)C , 5 atm, 5 moles) ( C_(P) of x_(2) = 6.95 cal/mol/ ""^(@)C ), log 1.3= 0.1139

The entropy change for the conversion of 1 mole of alpha-" tin" (at 13^(@)C, 1 atm) to 1 mole of beta-" tin "(13^(@)C, 1 atm) if the enthalpy of transition is 2.095 kJ mol^(-1)

What is entropy change?Predict the sign of entropy chsnge in each of the following giving reasons for your predictions : (i) H_(2) (at 25^(@)C, 1 atm) to H_(2)(at 25^(@)C and 10 atm)) (ii) H_(2)O(at 25^(@)C, 1 atm ) to H_(2)O(at 50^(@)C and 1 atm)) (iii) 2NH_(4)NO_(3)(s) to 2N_(2)(g) + 4H_(2)O(g) + O_(2)(g)

The entropy change of the conversion of 1 mol of alpha - tin (at 13^(@)C , 1 atm) to 1 mol of beta - tin( 13^(@) , 1 atm). If enthalpy of transition is 2.095 kJ mol^(-1) is :

Predict the entropy change (positive / negative) in the following: (i) CaCO_(3)(s) to CaO(s) + O_(2)(g) . (ii) N_(2)(g)(1 atm) to N_(2)(g) (0.5 atm) .

Calculate the change in entropy for the following process : 2 mol of N_(2) (l , 1 atm, -195.6^(@)C) to 2 " mol of " N_(2) (g, 1 " atm " -195.6^(@)C) [Given that, change in molar enthalpy for the vaporisation of N_(2)= 5.586 " kJ mol"^(-1) ]