Question

Question #e32d1

Answer 1

`"IO"_text(3(aq])^(-) + 5"I"_text((aq])^(-) + 6"H"_text((aq])^(+) -> 3"I"_text(2(aq]) + 3"H"_2"O"_text((l])`

Explanation:

The iodate, `"IO"_3^(-)`, and iodide, `"I"^(-)`, ions will react in acidic medium to form iodine, `"I"_2`.

Your starting equation will be

`"IO"_text(3(aq])^(-) + "I"_text((aq])^(-) + "H"_text((aq])^(+) -> "I"_text(2(aq]) + "H"_2"O"_text((l])`

Right from the start, you can probably tell that this is a disproportionation raction, which a redox reaction in which the same chemical species is being reduced and oxidized at the same time.

Assign oxidation numbers to all the atoms that take part in the reaction

`stackrel(color(blue)(+5))("I") stackrel(color(blue)(-2))("O"_3^(-)) + stackrel(color(blue)(-1))("I"^(-)) + stackrel(color(blue)(+1))("H"^(+)) -> stackrel(color(blue)(0))("I"_2) + stackrel(color(blue)(+1))("H"_2) stackrel(color(blue)(-2))("O")`

Some of the iodine atoms are being reduced from an oxidation state of +5 to an oxidation state of 0, while other are being oxidized from an oxidation state of -1 to an oxidation state of 0.

The two half-reactions will be

• oxidation half-reaction

`2stackrel(color(blue)(-1))("I"^(-)) -> stackrel(color(blue)(0))("I"_2) + 2e^(-)`

Each iodine atom loses one electrons, so two iodine atoms will lose 2 electrons.

• reduction half-reaction

`2stackrel(color(blue)(+5))("I")"O"_3^(-) + 10e^(-) -> stackrel(color(blue)(0))("I"_2)`

Each iodine atom will gain 5 electrons, which means that two iodine atoms will gain a total of 10 electrons* to form `"I"_2`.

Since you're in acidic solution, use water to balance the oxygen atoms and protons to balance the hydrogen atoms

`12"H"^(+) + 2stackrel(color(blue)(+5))("I")"O"_3^(-) + 10e^(-) -> stackrel(color(blue)(0))("I"_2) + 6"H"_2"O"`

In any redox reaction, the number of electrons lost in the oxidation half-reaction must be equal to the number of electrons gained in the reduction half-reaction.

This means that you need to multiply the oxidation half-reaction by `5` to get

`10"I"^(-) -> 5"I"_2 + 10e^(-)`

The two half-reactions will now be

`{(10"I"^(-) -> 5"I"_2 + 10e^(-)), (12"H"^(+) + 2"IO"_3^(-) + 10e^(-) -> "I"_2 + 6"H"_2"O") :}`

Add the two half-reaction to get

`10"I"^(-) + 12"H"^(+) + 2"IO"_3^(-) + color(red)(cancel(color(black)(10e^(-)))) -> 5"I"_2 + color(red)(cancel(color(black)(10e^(-)))) + "I"_2 + 6"H"_2"O"`

`2"IO"_text(3(aq])^(-) + 10"I"_text((aq])^(-) + 12"H"_text((aq])^(+) -> 6"I"_text(2(aq]) + 6"H"_2"O"_text((l])`

The balanced net ionic equation will thus be

`"IO"_text(3(aq])^(-) + 5"I"_text((aq])^(-) + 6"H"_text((aq])^(+) -> 3"I"_text(2(aq]) + 3"H"_2"O"_text((l])`