Question

Question #93e3a

Answer 1

`M = "0.116 mol/L"; ["Fe"^"3+"] = "0.116 mol/L";["Br"^"-"] = "0.349 mol/L"`

Explanation:

Molarity

The molarity of a solution is given by the expression

`color(blue)(bar(ul(|color(white)(a/a)"Molarity" = "moles"/"litres"color(white)(a/a)|)))" "`

or

`M = n/V`

where

`M =` molarity
`n =` number of moles
`V =` volume in litres

The molar mass of `"FeBr"_3` is 295.56 g/mol.

∴ `n = 12.9 color(red)(cancel(color(black)("g FeBr"_3))) × ("1 mol FeBr"_3)/(295.56 color(red)(cancel(color(black)("g FeBr"_3)))) = "0.043 65 mol FeBr"_3`

`V = 375 color(red)(cancel(color(black)("mL"))) × "1 L"/(1000 color(red)(cancel(color(black)("mL")))) = "0.375 L"`

`M = "0.043 65 mol FeBr"_3/"0.375 L" = "0.116 mol/L"`

Concentration of `"Fe"^"3+"`

The equation for the solution process is

`"FeBr"_3(s) → "Fe"^"3+""(aq)" + "3Br"^"-""(aq)"`

We see that 1 mol of `"FeBr"_3` gives 1 mol of `"Fe"^"3+"`.

∴ `["Fe"^"3+"] = (0.116 color(red)(cancel(color(black)("mol FeBr"_3))))/"1 L" × ("1 mol Fe"^"3+")/(1 color(red)(cancel(color(black)("mol FeBr"_3)))) = "0.116 mol/L"`

Concentration of `"Br"^"-"`

We see from the chemical equation that 1 mol of `"FeBr"_3` gives 3 mol of `"Br"^"-"`.

∴ `["Br"^"-"] = (0.116 color(red)(cancel(color(black)("mol FeBr"_3))))/"1 L" × ("3 mol Br"^"-")/(1 color(red)(cancel(color(black)("mol FeBr"_3)))) = "0.349 mol/L"`