`CO+I_(2)O_(5)(s) to CO_(2)+I_(2)`

XO+I_(2)O_(5)(s) to CO_(2)+I_(2)

A mixture of CO and CO_(2) when treated with I_(2)O_(5) gives I_(2) vapours accoeding to the following equation: 5CO+I_(2)O_(5)to5CO_(2)+I_(2) I_(2) vapour was separated and treated with HClO_(4) and the resultant HIO_(4) required 0.001 " mol of "hlycerol for complete oxidation. After treatment with I_(2)O_(5) and removal of I_(2) ,t he mixture was treated with excess of 0.1 N NaOH solution and finally this solution required 20 " mL of " 1 N HCl to reach end point using phenolphthalein as indicator, followed by methyl orange as indicator after the first end point, 10 " mL of " further HCl was consumed. Q. Total number of millimoles of CO_(2) in the above problem is

A mixture of CO and CO_(2) when treated with I_(2)O_(5) gives I_(2) vapours accoeding to the following equation: 5CO+I_(2)O_(5)to5CO_(2)+I_(2) I_(2) vapour was separated and treated with HClO_(4) and the resultant HIO_(4) required 0.001 " mol of "hlycerol for complete oxidation. After treatment with I_(2)O_(5) and removal of I_(2) ,t he mixture was treated with excess of 0.1 N NaOH solution and finally this solution required 20 " mL of " 1 N HCl to reach end point using phenolphthalein as indicator, followed by methyl orange as indicator after the first end point, 10 " mL of " further HCl was consumed. Q. The number of moles of CO present initially is

A mixture of CO and CO_(2) when treated with I_(2)O_(5) gives I_(2) vapours accoeding to the following equation: 5CO+I_(2)O_(5)to5CO_(2)+I_(2) I_(2) vapour was separated and treated with HClO_(4) and the resultant HIO_(4) required 0.001 " mol of "hlycerol for complete oxidation. After treatment with I_(2)O_(5) and removal of I_(2) ,t he mixture was treated with excess of 0.1 N NaOH solution and finally this solution required 20 " mL of " 1 N HCl to reach end point using phenolphthalein as indicator, followed by methyl orange as indicator after the first end point, 10 " mL of " further HCl was consumed. Q. The total volume of NaOH used in the problem is

Write the expressioin for the equilibrium constant for each of the following reactions? (i) 2NOCl(g) ltimplies 2NO(g) + Cl_(2)(g) (ii) C(s) +CO_(2) (g) hArr 2CO(g) (iii) I_(2) (s) + 5F_(2) (g) hArr 2IF_(5) (g) (iv) FeO(s) +CO(g) hArr Fe (s) +CO_(2)(g) (v) Na_(2) CO_(3) (s) + SO_(2) (g) +1//2O_(2) (g) hArr Na_(2)SO_(4)(s) + CO_(2) (g).

Select the reaction which describes the existence of I_(2)O_(5)(s) as (IO_(2)^(+))(IO_(3)^(-)) :

The CO in a 20.3L sample of gas was converted to CO_(2) by passing the gas over iodine pentoxide heated to 150^(@)C : I_(2)O_(5)(s)+5CO(g)rarr5CO_(2)(g)+I_(2)(g) The iodine distilled at this temperature and was collected in an absorber containing 8.25mL of 0.11101M Na_(2)S_(2)O_(3) . The excess hypo was back-titrated with 2.16mL of 0.00947M I_(2) solution. The milligrams of CO in 1L of the original gas sample was therefore:

Match the term given in Column I withthe equation given in Column II {:("Column I " , "Column II") , ("(A) Enthalpy of formation", (p) CuSO_(4) (s) + 5 H_(2) O (l) to CuSO_(4) 5H_(2)O), ("(B) Enthalpy of combustion" , (q) CuSO_(4) (s) + nH_(2) O (l) to CuSO_(4) (aq)),("(C) Enthalpy of solution " , (r) C(s) + O_(2) (g) to CO_(2) (g)) , ("(D) Enthalpy of hydration" , (s) CH_(4) + 2 O_(2) to CO_(2) + 2 H_(2)O):}

Which statements in each of the following paris would you except to have the higher standard molar entropy? (I) C_(2)H_(2)(g) or C_(2)H_(6) (g), (II) CO_(2)(g) or CO(g), (III) I_(2) (s) or I_(2) (g) The correct choice is:

The percentage of oxygen in an organic compound can be determined by converting O of the compound quantitatively into (i) CO_(2) (ii) I_(2)O_(5) (iii) I_(2) (iv) CO