Preidict what will happern if molecular bromine `(Br_(2))` is added to a solution containing `NaCl` and `NaI` at `25^(@)C`. Assume all species are in their standard states.A. `Cl_(2)(g)` is realeasedB. `I_(2)(s)` is obtainedC. Both `Cl_(2)` and `I_(2)` are obtainedD. Neither `Cl_(2)` nor `I_(2)` is obtained

Preidict what will happern if molecular bromine `(Br_(2))` is added to

1.	Preidict what will happern if molecular bromine `(Br_(2))` is added to a solution containing `NaCl` and `NaI` at `25^(@)C`. Assume all species are in their standard states.A. `Cl_(2)(g)` is realeasedB. `I_(2)(s)` is obtainedC. Both `Cl_(2)` and `I_(2)` are obtainedD. Neither `Cl_(2)` nor `I_(2)` is obtained
Answer» Correct Answer - B To predict what redox reactions will take place, we need to compare the standard reduction potential for the following half reactions: `{:(I_(2)(s)+2e^(-)hArr2I^(-)(aq., 1M)E^(@)=0.53V),(Br_(2)(l)+2e^(-)hArr2Br^(-)(aq., 1M)E^(@)=1.07 V),(Cl_(2)(g,1 "bar")+2e^(-)hArr 2Cl^(-)(aq.,1M)E^(@)=1.36V):}` Since `E_(Br_(2)//Br^(-))^(@)gtE_(I_(2)//I^(-))^(@),Br_(2)` gets reduced by `I^9-)` i.e. `Br_(2)` will oxidized `I^(-)`. Since `E_(Br_(2)//Br^(-))^(@)gtE_(I_(2)//I^(-))^(@)`, `Br_(2)` will not oxidize `Cl^(-)`. Therefore, the only redox reaction that will occur appreciably under standard state conditions is `{:("Oxidation"2I^(-)(aq.,1M)hArrI_(2)(s)+2e^(-)),("Reduction" Br_(2)(l)+2e^(-)hArr 2Br^(-)(aq.,1M)),(bar("Overall" 2I^(-)(aq.,1M)+Br_(2)(l)hArr I_(2)(s)+2Br(aq., 1M))):}` Note that the `Na^(+)` ions are inert and do not enter into the redox reaction.

Discussion

No Comment Found

Related InterviewSolutions

Define molar conductivity of a solution and explain how molar conductivity changes with change in concentration of a solution for a weak and a strong electrolyte.
Limiting molar conductivity of `NH_(4)OH` [i.e., `Lambda_(m)^(@)(NH_(4)OH)`] is equal to:A. `Lambda_(m (NH_(4)Cl ))^(@) + Lambda_(m (NaCl))^(@) - Lambda_(m(NaOH))^(@)`B. `Lambda_(m (NaOH))^(@) + Lambda_(m(NaCl))^(@) - Lambda_(m(NH_(4)Cl))^(@)`C. `Lambda_(m(NH_(4)OH))^(@) + Lambda_(m (NH_(4)Cl))^(@) - Lambda_(m(HCl))^(@)`D. `Lambda_(m (NH_(4)Cl))^(@) + Lambda_(m (NaOH))^(@) - Lambda_(m(NaCl))^(@)`
Limiting molar conductivity of `NH_(4)OH` [i.e., `Lambda_(m)^(@)(NH_(4)OH)`] is equal to:A. `Lambda_(m)^(@)(NH_(4)Cl)+Lambda_(m)^(@)(Na_(4)Cl)-Lambda_(m)^(@)(NaOH)`B. `Lambda_(m)^(@)(NaOH)+Lambda_(m)^(@)(NaCl)-Lambda_(m)^(@)(NH_(4)Cl)`C. `Lambda_(m)^(@)(NH_(4)OH)+Lambda_(m)^(@)(NH_(4)Cl)-Lambda_(m)^(@)(HCl)`D. `Lambda_(m)^(@)(NH_(4)Cl)+Lambda_(m)^(@)(NaOH)-Lambda_(m)^(@)(NaCl)`
For the cell reaction `Cu^(2+)(C_(1),aq.)+Zn(s)hArrZn^(2+)(C_(2),aq)+Cu(s)` of an electrochemical cell, the change in free energy `(DeltaG)` of a given temperature is a function ofA. `lnC_(1)`B. `lnC_(2)//C_(1)`C. `ln (C_(1) + C_(2))`D. `ln C_(2)`
Use of lithium metal as an electrode in high energy density batteries is due to:A. Lithium is highest elementB. Lithium has highest oxidation potentialC. Lithium is quite reactiveD. Lithium does not corrode readily
The Gibbs energy for the decomposition of `Al_(2)O_(3)` at `500^(@)C` is as follow : `(2)/(3)Al_(2)O_(3) rarr (4)/(3)Al+O_(2), Delta_(r)G= +960 kJ mol^(-1)` The potential difference needed for the electrolytic reduction of aluminium oxide `(Al_(2)O_(3))` at `500^(@)C` isA. `5.0 V`B. `4.5 V`C. `3.0 V`D. `2.5 V`
Based on the data given below, the correct order of reducing power is: `Fe_((aq.))^(3+) + e rarr Fe_((aq.))^(2+), E^(@) = +0.77 V` `Al_((aq.))^(3+) + 3e rarr Al_((s)), E^(@) = -1.66 V` `Br_(2(aq.)) + 2e rarr 2Br_((aq.))^(-), E^(@) = +1.08 V`A. `Br^(-) lt Fe^(2+) lt A1`B. `Fe^(2+) lt Al lt Br^(-)`C. `Al^(-) lt Br^(-) lt Fe^(2+)`D. `Al^(-) lt Fe^(2+) lt Br^(-)`
Based on the data given below, the correcy order of reducing power is: `Fe_((aq.))^(3+) + e rarr Fe_((aq.))^(2+), E^(@) = +0.77 V` `Al_((aq.))^(3+) + 3e rarr Al_((s)), E^(@) = -1.66 V` `Br_(2(aq.)) + 2e rarr 2Br_((aq.))^(-), E^(@) = +1.08 V`A. `Br^(-) lt Fe^(2+) lt Al`B. `Fe^(2+) lt Al lt Br^(-)`C. `Al lt Br^(-) lt Fe^(2+)`D. `Al lt Fe^(2+) lt Br^(-)`
Based on the data given below, the correcy order of reducing power is: `Fe_((aq.))^(3+) + e rarr Fe_((aq.))^(2+), E^(@) = +0.77 V` `Al_((aq.))^(3+) + 3e rarr Al_((s)), E^(@) = -1.66 V` `Br_(2(aq.)) + 2e rarr 2Br_((aq.))^(-), E^(@) = +1.08 V`A. `Br^(-) lt Fe^(2+) lt Al`B. `Fe^(2+) lt Al lt Br^-`C. `Al lt Br^(-) lt Fe^(2+)`D. `Al lt Fe^(2+) lt Br^(-)`
What are elementary reactions ?

Discussion

No Comment Found

Related InterviewSolutions

Reply to Comment