Question

How should I go about writing a procedure for this Chem lab? (see Details)

I am given 25mL of an aqueous solution containing the ionic compounds `HNO_3`, `Sr(NO_3)_2`, and `AgNO_3`.

I must discover the concentrations of each of the ionic compounds in the solution above using four known solutions of `KCl`(0.15M), `Na_3PO_4`(0.15M), `K_2SO_4`(0.15M), and `NaOH`(0.25M).

I don't have to use all of the solutions of I do not need them. Also, my partner is as clueless as I am, so there's not much help from that direction.

Answer 1

Given `"25 mL"` of a solution containing `"HNO"_3`, `"Sr"("NO"_3)_2`, and `"AgNO"_3` (all water-soluble), we have `"0.15 M KCl"`, `"0.15 M Na"_3"PO"_4`, `"0.15 M K"_2"SO"_4`, and `"0.25 M NaOH"` available.

The idea is to choose reagents that react specifically with what you want to suss out. You'll want to do this in a sequence, accounting for dilutions.

This is what I would suggest as a procedure:

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[Click on the image to zoom in.]

To summarize:

1. Measure pH to get `["HNO"_3]` right away.

2. React the starting solution with excess `"KCl"` (I chose `"10.00 mL"` because it's the volume of a `"10.00-mL"` volumetric pipette and it's probably excess of what is needed to precipitate `"AgCl"(s)`). Relevant reagent = `"AgNO"_3`.

3. Separate the precipitate from the supernatant, and put the supernatant to the side for step 5. Weigh a piece of filter paper.

4. Filter the `"AgCl"` precipitate from step 2 using that filter paper, dry it, weigh it, and get the mass of filter paper+`"AgCl"`. The `["Ag"^(+)]` links `"AgCl"` to `["AgNO"_3]`, so we don't worry about excess `"Cl"^(-)` we added in.

5. React the supernatant from step 3 (relevant reagent = `"SrCl"_2`) with excess `"Na"_3"PO"_4` (again, convenient volume) and form `"Sr"_3("PO"_4)_2(s)` precipitate.

6. Separate the precipitate from the supernatant, and discard the supernatant! Weigh a new piece of filter paper.

7. Filter the `"Sr"_3("PO"_4)_2` precipitate from step 5, dry it, weigh it, and get the mass of filter paper+`"Sr"_3("PO"_4)_2`. The `["Sr"^(2+)]` links `"Sr"_3("PO"_4)_2(s)` to `["SrCl"_2]` and thus `["Sr"("NO"_3)_2]`, so we don't worry about excess `"PO"_4^(3-)` we added in.

Below are all my brainstorming thoughts.

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Here's my brainstorm (all given molar solubilities are in pure water at `20^@ "C"`), using `K_(sp)` values from here and here:

• `"NaOH"` is NOT needed.

Simply measure the pH of the starting solution to find `["H"^(+)]` and thus `["HNO"_3]`.

Good method to get `["H"^(+)]`? `color(blue)(sqrt"")`

• `"K"_2"SO"_4` will react with `"HNO"_3` to form `"HSO"_4^(-)`, with `"Sr"("NO"_3)_3` to form `"SrSO"_4(s)` (`K_(sp) = 3.44 xx 10^(-7)`), and with `"AgNO"_3` to form `"Ag"_2"SO"_4(s)` (`K_(sp) = 1.20 xx 10^(-5)`).

Both precipitates are white, unfortunately, but their corresponding molar solubilities are `5.87 xx 10^(-4) "M"` and `"0.0144 M"`, respectively.

Good method to get `["Sr"^(2+)]`? (Possibly, depends on previous steps)

• `"Na"_3"PO"_4` would precipitate heavily to form `"Sr"_3("PO"_4)_2` (`K_(sp) = 1.0 xx 10^(-31)`) and `"Ag"_3"PO"_4` (`K_(sp) = 8.89 xx 10^(-17)`), with corresponding molar solubilities of `2.47 xx 10^(-7) "M"` and `4.26 xx 10^(-5) "M"`, respectively.

Good method to get `["Sr"^(2+)]`? (Possibly, depends on previous steps)

• `"KCl"` would react selectively with `"AgNO"_3` to form the white `"AgCl"(s)` with no interferences, so this is a great choice to get `["Ag"^(+)]`.

`"SrCl"_2` is very soluble, no problem there, and solid `"KCl"` reacts with concentrated `"HNO"_3` but not when they're both aqueous.

Good method to get `["Ag"^(+)]`? `color(blue)(sqrt"")`