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Concentration of Solutions and the Concentration/Volume Relationship Prepared By Michigan Department of Environmental Quality Operator Training and Certification.

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Presentation on theme: "Concentration of Solutions and the Concentration/Volume Relationship Prepared By Michigan Department of Environmental Quality Operator Training and Certification."— Presentation transcript:

1 Concentration of Solutions and the Concentration/Volume Relationship Prepared By Michigan Department of Environmental Quality Operator Training and Certification Unit

2 CONCENTRATION Amount of a Substance in a unit Amount of Solution WEIGHT Per Unit VOLUME OR WEIGHT / VOLUME GRAMS / LITER or Milligrams / Liter mg/L

3 CONCENTRATION WEIGHT / VOLUME Weight per Unit Volume Times Number of Units of Volume Equals Total Weight of Substance in Total Volume of Solution OR Concentration X Volume = Weight

4 One liter of a solution contains 100 mg of phosphorus. How much (Wt.) phosphorus would be in 50 mL of this solution? Conc. (mg/L) X Volume (L) = Weight 100 mg/LX50 mL X mL L 1 1000 = Wt. 100 mg L X 50. 1000 L = Wt. 5.0mg = Wt.

5 How much phosphorus would be in a solution made by adding enough water to this 50 mL to dilute it to one liter? The amount (Wt.) of phosphorus would not change. 5.0 mg of phosphorus would be in the solution.

6 What would be the concentration of the new solution? Concentration = Wt./Vol. = mg/L Concentration = 5.0 mg/L

7 Conc. (mg/L) X Volume (L) = Weight (mg) When Making a Dilution Two Solutions Before and After Adding Water Abbreviated C X V = W

8 Conc. (mg/L) X Volume (L) = Weight (mg) When Making a Dilution Let the Subscript 1 refer to the solution Before dilution and Let the Subscript 2 refer to the solution After dilution then C 1 X V 1 = W 1 and C 2 X V 2 = W 2

9 BUT Weight before dilution = Weight after dilution OR W 1 = W 2 THEREFORE C 1 X V 1 = W 1 = W 2 = C 2 X V 2 and C 1 X V 1 = C 2 X V 2

10 EXAMPLE 1 What would be the final concentration of a solution made by diluting 50 mL of a 100 mg/L phosphorus solution to one Liter? C 1 X V 1 = C 2 X V 2 C 1 = Initial Concentration V 1 = Initial Volume C 2 = Final Concentration V 2 = Final Volume (mg/L or N) (mL or Liter) Note that the terms tell if the value is a Volume or a Concentration mg/L or Normality (N) – always Concentration (C) Liter or mL – always Volume (V)

11 EXAMPLE 1 C 1 X V 1 = C 2 X V 2 C 1 = Initial Concentration V 1 = Initial Volume C 2 = Final Concentration V 2 = Final Volume (mg/L or N) (mL or Liter) Note that the terms tell if the value is a Volume or a Concentration of – links a Concentration with a Volume (Either C 1 and V 1 or C 2 and V 2 ) to – indicates initial (1) and final (2) water was added to V 1 OR V 1 was diluted to V 2 What would be the final concentration of a solution made by diluting 50 mL of a 100 mg/L phosphorus solution to one Liter?

12 EXAMPLE 1 C 1 X V 1 = C 2 X V 2 C 1 = Initial Concentration V 1 = Initial Volume C 2 = Final Concentration V 2 = Final Volume (mg/L or N) (mL or Liter) = 50 mL = 100 mg/L = ? = 1 Liter= 1000 mL 100 mg/LX50 mL= C2C2 X1000 mL = C 2 100 X 50 1000 mg/L 5.0 mg/L = C 2 What would be the final concentration of a solution made by diluting 50 mL of a 100 mg/L phosphorus solution to one Liter?

13 EXAMPLE 2 What would be the final concentration of a solution made by diluting 10 mL of a 250 mg/L phosphorus solution to one Liter? C 1 X V 1 = C 2 X V 2 C 1 = Initial Concentration V 1 = Initial Volume C 2 = Final Concentration V 2 = Final Volume (mg/L or N) (mL or Liter) = 10 mL = 250 mg/L = ? = 1 Liter= 1000 mL 250 mg/LX10 mL= C2C2 X1000 mL = C 2 250 X 10 1000 mg/L 2.5 mg/L = C 2

14 EXAMPLE 3 What would be the final concentration of a solution made by diluting 100 mL of a 24.0 mg/L phosphorus solution with 500 ml of distilled water? C 1 X V 1 = C 2 X V 2 C 1 = Initial Concentration (mg/L or N) V 1 = Initial Volume (mL or Liter) C 2 = Final Concentration (mg/L or N) V 2 = Final Volume (mL or Liter) = 100 mL = 24.0 mg/L = ? = 500 mL= 600 mL 24.0 mg/LX100 mL= C2C2 X600 mL = C 2 24.0 X 100 600 mg/L 4.0 mg/L = C 2 + 100 mL

15 EXAMPLE 4 How many milliliters of a 50 mg/L phosphorus solution would be needed to make 50 mL of a 2.0 mg/L solution? C 1 X V 1 = C 2 X V 2 C 1 = Initial Concentration V 1 = Initial Volume C 2 = Final Concentration V 2 = Final Volume (mg/L or N) (mL or Liter) = ? = 50 mg/L = 2.0 mg/L = 50 mL 50 mg/LXV1V1 = 2.0 mg/L X50 mL 50 mg/L V 1 = 2.0 X 50 50 mL V 1 = 2.0 mL

16 1. What would be the concentration of a solution made up by diluting 5 mL of a 250 mg/L solution to 100 mL? Practice Problems 2. 100 mL of a 25 mg/L stock zinc solution is diluted to one Liter. What is the concentration of zinc in the final solution? 3. How many mL of a 500 mg/L solution are needed to make one liter of a 25 mg/L solution? 4. 4 mL of a sample was diluted to 100 mL in a volumetric flask. The diluted solution was analyzed and found to have a concentration of 2.0 mg/L. What was the concentration of the original sample? 5. To dilute 100 mL of a 50 mg/L solution to get a 20 mg/L solution, how much water must be added? 6. How many milliliters of distilled water must be added to 950 mL of 0.01295 N sodium thiosulfate to get a solution with a concentration of 0.0125 N sodium thiosulfate? Work Calculations on Separate Paper Answers Given on Next Slides

17 1. What would be the concentration of a solution made up by diluting 5 mL of a 250 mg/L solution to 100 mL? C 1 x V 1 = C 2 x V 2 12.5 mg/L = C 2 250 mg/L 100 mL 5 mL x = C2C2 x 100 mL 250 x 5 100 = C 2 mg/L C 1 = V 1 = C 2 = V 2 = 250 mg/L 5 mL ? 100 mL

18 C 1 x V 1 = C 2 x V 2 25 mg/L x 100 mL = C 2 x 1000 mL 1000 mL 25 x 100 1000 mg/L 2.5 mg/L = C 2 = C 2 2. 100 mL of a 25 mg/L stock zinc solution is diluted to one Liter. What is the concentration of zinc in the final solution? C 1 = V 1 = C 2 = V 2 = 25 mg/L 100 mL ? 1 L = 1000 mL

19 3. How many mL of a 500 mg/L solution are needed to make one liter of a 25 mg/L solution? 500 mg/L x V 1 = 25 mg/L x 1000 mL 500 mg/L 500 mg/L 25 x 1000 500 V 1 = V 1 = 50 mL mL C 1 x V 1 = C 2 x V 2 C 1 = V 1 = C 2 = V 2 = 500 mg/L 25 mg/L 1 Liter = 1000 mL ?

20 C 1 x V 1 = C 2 x V 2 C 1 x 4 mL = 2.0 mg/L x 100 mL 4 mL 2.0 x 100 4 mg/L 50.0 mg/L = C 1 C1=C1= 4. 4 mL of a sample was diluted to 100 mL in a volumetric flask. The diluted solution was analyzed and found to have a concentration of 2.0 mg/L. What was the concentration of the original sample? C 1 = V 1 = C 2 = V 2 = 2.0 mg/L 4 mL ? 100 mL

21 5. To dilute 100 mL of a 50 mg/L solution to get a 20 mg/L solution, how much water must be added? C 1 x V 1 = C 2 x V 2 50 mg/L x 100 mL = 20 mg/L x V2V2 20 mg/L 20 mg/L 250 mL = V 2 50 x 100 20 mL = V 2 C 1 = V 1 = C 2 = V 2 = 50 mg/L 100 mL 20 mg/L ?

22 5. To dilute 100 mL of a 50 mg/L solution to get a 20 mg/L solution, how much water must be added? C 1 x V 1 = C 2 x V 2 250 mL = V 2 C 1 = V 1 = C 2 = V 2 = 50 mg/L 100 mL 20 mg/L ? - 100 mL 150 mL Water to be Added

23 6. How many milliliters of distilled water must be added to 950 mL of 0.01295 N sodium thiosulfate to get a solution with a concentration of 0.0125 N sodium thiosulfate? N 1 x V 1 = N 2 x V 2 0.01295 N X 950 mL = 0.0125 N X V 2 0.0125 N 0.0125 N 984.2 mL = V 2 0.01295 x 950 0.0125 = V 2 mL - 950.0 mL 34.2 mL Water to be Added

24 Concentration of Solutions and the Concentration/Volume Relationship Prepared By Michigan Department of Environmental Quality Operator Training and Certification Unit

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