Concentration and dilution practice worksheet answers

Problem #1: If you dilute 175 mL of a 1.6 M solution of LiCl to 1.0 L, determine the new concentration of the solution.

Note that 1000 mL was used rather than 1.0 L. Remember to keep the volume units consistent.

Problem #2: You need to make 10.0 L of 1.2 M KNO₃. What molarity would the potassium nitrate solution need to be if you were to use only 2.5 L of it?

Please note how I use the molarity unit, mol/L, in the calculation rather than the molarity symbol, M.

Problem #3: How many milliliters of 5.0 M copper(II) sulfate solution must be added to 160 mL of water to achieve a 0.30 M copper(II) sulfate solution?

M₁V₁ = M₂V₂

(5.00 mol/L) (x) = (0.3 mol/L) (160 + x)

5x = 48 + 0.3x

4.7x = 48

x = 10. mL (to two sig figs)

The solution to this problem assumes that the volumes are additive. That's the '160 + x' that is V₂.

Problem #4: What volume of 4.50 M HCl can be made by mixing 5.65 M HCl with 250.0 mL of 3.55 M HCl?

Here is the first way to solve this problem:

M₁V₁ + M₂V₂ = M₃V₃

(3.55) (0.250) + (5.65) (x) = (4.50) (0.250 + x)

Where x is volume of 5.65 M HCl that is added
(0.250 + x) is total resultant volume

0.8875 + 5.65x = 1.125 + 4.50 x
1.15x = 0.2375
x= 0.2065 L

Total amount of 4.50 M HCl is then (0.250 + 0.2065) = 0.4565 L
Total amount = 456.5 mL

Here is the second way to solve this problem:

Since the amount of 5.65 M added is not asked for, there is no need to solve for it.

M₁V₁ + M₂V₂ = M₃V₃

(3.55) (250) + (5.65) (x − 250) = (4.50) (x)

That way, x is the answer you want, the final volume of the solution, rather than x being the amount of 5.65 M solution that is added.

Problem #5: A 40.0 mL volume of 1.80 M Fe(NO₃)₃ is mixed with 21.5 mL of 0.808M Fe(NO₃)₃ solution. Calculate the molar concentration of the final solution.

Let's use a slightly different way to write the subscripts:

M₁V₁ + M₂V₂ = M₃V₃

There is no standard way to write the subscripts in problems of this type.

Problem #6: To 2.00 L of 0.445 M HCl, you add 3.88 L of a second HCl solution of an unknown concentration. The resulting solution is 0.974 M. Assuming the volumes are additive, calculate the molarity of the second HCl solution.

1) Calculate moles HCl in 0.445 M solution:

(0.445 mol/L) (2.00 L) = 0.890 moles

2) Set up expression for moles of HCl in second solution:

(x) (3.88 L) = moles HCl in unknown solution

3) Calculate moles of HCl in final solution:

(0.974 mol/L) (5.88 L) = 5.73 moles

4) Moles of HCl in two mixed solutions = moles of HCl in final solution:

0.890 moles + [(x) (3.88 L)] = 5.73 moles

x = 1.25 M (to three sig figs)

Problem #7: To what volume should you dilute 133 mL of an 7.90 M CuCl₂ solution so that 51.5 mL of the diluted solution contains 4.49 g CuCl₂?

(4.49g CuCl₂) (1 mole CuCl₂ / 134.45 grams) = 0.033395 moles CuCl₂

2) Find the molarity of the 51.5 mL of the diluted solution that contains 4.49g CuCl₂:

(0.033395 moles CuCl₂) / (0.0515 liters) = 0.648 M

3) Use the dilution formula:

You should dilute the 133 mL of an 7.90 M CuCl₂ solution to 1620 mL.

Problem #8: If volumes are additive and 95.0 mL of 0.55 M KBr is mixed with 165.0 mL of a BaBr₂ solution to give a new solution in which [Br¯] is 0.65 M, what is the concentration of the BaBr₂ used to make the new solution?

moles of Br¯ from KBr: (0.55 mol/L) (0.095 L) = 0.05225 mol

moles of Br¯ in final solution: (0.65 mol/L) (0.260 L) = 0.169 mol

moles Br¯ provided by the BaBr₂ solution: 0.169 − 0.05225 = 0.11675 mol

BaBr₂ provides two Br¯ per formula unit so (0.11675 divided by 2) moles of BaBr₂ are required for 0.11675 moles of Br¯ in the solution.

molarity of BaBr₂ solution: 0.058375 mol / 0.165 L = 0.35 M

Problem #9: 1.00 L of a solution is prepared by dissolving 125.6 g of NaF in it. If I took 180 mL of that solution and diluted it to 500 mL, determine the molarity of the resulting solution.

1) Calculate moles of NaF:

125.6 g / 41.9 g/mol = 3.00 mol

2) Calculate moles in 180 mL of resulting solution:

3.00 mol in 1000 mL so 3 x (180/1000) = 0.54 mol in 180 mL

3) Calculate molarity of diluted solution:

0.54 mol / 0.50 L = 1.08 mol/L = 1.08 M

Problem #10: What is the molar concentration of chloride ions in a solution prepared by mixing 100.0 mL of 2.0 M KCl with 50.0 mL of a 1.50 M CaCl₂ solution?

(Warning: there's a complication in the solution. It has to do with the CaCl₂.)

1) Get total moles of chloride:

KCl ⇒ (2.00 mol/L) (0.100 L) = 0.200 mol of chloride ion

CaCl₂ ⇒ (1.50 mol/L) (0.0500 L) (2 ions / 1 formula unit) = 0.150 mol of chloride ion.

The '2 ions / 1 formula unit' is the problem child. The solution is 1.50 M in calcium chloride, but 3.00 M in just chloride ion.

total moles = 0.200 mol + 0.150 mol = 0.350 mol

2) Get chloride molarity:

0.350 mol / 0.150 L = 2.33 M

Suppose you really wanted to use this equation:

M₁V₁ + M₂V₂ = M₃V₃

Set it up like this:

(2.00 mol/L) (0.100 L) + (3.00 mol/L) (0.0500 L) = (M₃) (0.150 L)

Note that the CaCl₂ molarity is 3.00 because that is the molarity of the solution from the point-of-view of the chloride ion.

Bonus Problem: What volume of a 30.% (w/v) hydrogen peroxide solution is required to prepare 425 mL of a 6.0% (w/v) solution?

1) 6.0% (w/v) means 6 g per 100 ml of solution:

x = 25.5 g

We must use sufficient 30.% (w/v) solution to provide 25.5 g of H₂O₂.

2) 30.% (w/v) means 30 g of solute per 100 mL of solution:

3) This question can be written so as to ask for the mass of 30.% (w/v) required. To do this, we follow the above steps, then this:

(85 mL) (1.10 g/mL) = 93.5 mL

The density of the solution is required, which necessitates some Internet searching. Here is an example of a site which gives a value for the density.