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© Copyright 1995-2010 R.J. Rusay Aqueous Solutions Concentration / Calculations Dr. Ron Rusay.

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Presentation on theme: "© Copyright 1995-2010 R.J. Rusay Aqueous Solutions Concentration / Calculations Dr. Ron Rusay."— Presentation transcript:

1 © Copyright 1995-2010 R.J. Rusay Aqueous Solutions Concentration / Calculations Dr. Ron Rusay

2 © Copyright 1995-2010 R.J. Rusay Solutions  Homogeneous solutions are comprised of solute(s), the substance(s) dissolved, [The lesser amount of the component(s) in the mixture], and  solvent, the substance present in the largest amount.  Solutions with less solute dissolved than is physically possible are referred to as “unsaturated”. Those with a maximum amount of solute are “saturated”.  Occasionally there are extraordinary solutions that are “supersaturated” with more solute than normal.

3 © Copyright 1995-2010 R.J. Rusay Concentration and Temperature Relative Solution Concentrations: Saturated Unsaturated Supersaturated Refer to: Lab Manual & Workshop

4 © Copyright 1995-2010 R.J. Rusay DHMO, dihydromonoxide : “The Universal” Solvent http://www.dhmo.org

5 © Copyright 1995-2010 R.J. Rusay Water : “The Universal” Solvent Generally, likes dissolve likes, i.e. polar-polar and nonpolar-nonpolar. If polar and nonpolar mix, eg. oil and water: The oil (nonpolar) and water (polar) mixture don’t mix and are immiscible. If liquids form a homogeneous mixture, they are miscible.

6 QUESTION

7 ANSWER

8 © Copyright 1995-2010 R.J. Rusay Aqueous Reactions & Solutions  Many reactions are done in a homogeneous liquid or gas phase which generally improves reaction rates.  The prime medium for many inorganic reactions is water which serves as a solvent (the substance present in the larger amount), but does not react itself.  The substance(s) dissolved in the solvent is (are) the solute(s). Together they comprise a solution. The reactants would be the solutes.  Reaction solutions typically have less solute dissolved than is possible and are “unsaturated”.

9 © Copyright 1995-2010 R.J. Rusay Salt dissolving in a glass of water Refer to Lab Manual & Workshop:

10 © Copyright 1995-2010 R.J. Rusay Water dissolving an ionic solid

11 © Copyright 1995-2010 R.J. Rusay Solution Concentrations Refer to Lab Manual  A solution’s concentration is the measure of the amount of solute dissolved.  Concentration is expressed in several ways. One way is mass percent. Mass % = Mass solute / [Mass solute + Mass solvent ] x100  What is the mass % of 65.0 g of glucose dissolved in 135 g of water? Mass % = 65.0 g / [65.0 + 135]g x 100 = 32.5 % = 32.5 %

12 © Copyright 1995-2010 R.J. Rusay Solution Concentration  Concentration is expressed more importantly as molarity (M). Molarity (M) = Moles solute / Liter Solution  An important relationship is M x V solution = mol  This relationship can be used directly in mass calculations of chemical reactions.  What is the molarity of a solution of 1.00 g KCl in 75.0 mL of solution? M KCl = [1.00g KCl / 75.0mL ][1mol KCl / 74.55 g KCl ][ 1000mL / L] = 0.18 mol KCl / L

13 QUESTION

14 ANSWER Is the acid solution’s concentration of H+ equal to F-?

15 © Copyright 1995-2010 R.J. Rusay HCl 1.0M 100% Ionized Acetic Acid (HC 2 H 3 O 2 ) < 100% Ionized Refer to Lab Manual Solution Concentrations: Solute vs. Ion Concentrations [H+] = [Cl-] = 1.0M[H+] = [C 2 H 3 O 2 -] < 1.0M

16 QUESTION Solutions: molarity & volume  mass

17 ANSWER B)5.11 g Volume(L) times concentration(mol/L) gives moles. Moles are then converted to grams. Electrolyte & Ionic Reactions Post Lab Questions http://chemconnections.org/general/chem120/solutions-mixes.html

18 © Copyright 1995-2010 R.J. Rusay Preparation of Solutions

19 © Copyright 1995-2010 R.J. Rusay Preparing a Standard Solution

20 QUESTION

21 ANSWER

22 © Copyright 1995-2010 R.J. Rusay Solution Concentration  The following formula can be used in dilution calculations: M 1 V 1 = M 2 V 2 M 1 V 1 = M 2 V 2  A concentrated stock solution is much easier to prepare and then dilute rather than preparing a dilute solution directly. Concentrated sulfuric acid is 18.0M. What volume would be needed to prepare 250.mL of a 1.50M solution?  V 1 = M 2 V 2 / M 1  V 1 = 1.50 M x 250. mL / 18.0 M  V 1 = 20.8 mL

23 QUESTION

24 ANSWER M  12 V, V A)168 mL Use the dilution formula, 1 V = M  2 M is in mol/L and is in L.

25 © Copyright 1995-2010 R.J. Rusay Solution Dilution

26 © Copyright 1995-2010 R.J. Rusay Solution Applications A solution of barium chloride was prepared by dissolving 26.0287 g in water to make 500.00 mL of solution. What is the concentration of the barium chloride solution? M BaCl2 = ? M BaCl2 M BaCl2 = = [26.0287g BaCl2 / 500.00mL ][1mol BaCl2 / 208.23g BaCl2 ] [1000mL / L] = 0.25000 mol / L

27 What happens to the number of moles of C 12 H 22 O 11 (sucrose) when a 0.20 M solution is diluted to a final concentration of 0.10 M? A) The number of moles of C 12 H 22 O 11 decreases. B) The number of moles of C 12 H 22 O 11 increases. C) The number of moles of C 12 H 22 O 11 does not change. D) There is insufficient information to answer the question. QUESTION

28 What happens to the number of moles of C 12 H 22 O 11 (sucrose) when a 0.20 M solution is diluted to a final concentration of 0.10 M? A) The number of moles of C 12 H 22 O 11 decreases. B) The number of moles of C 12 H 22 O 11 increases. C) The number of moles of C 12 H 22 O 11 does not change. D) There is insufficient information to answer the question. ANSWER

29 © Copyright 1995-2010 R.J. Rusay Solution Applications 10.00 mL of this solution was diluted to make exactly 250.00 mL of solution which was then used to react with a solution of potassium sulfate. What is the concentration of the diluted solution. M 2 = ? M BaCl2 M 1 M BaCl2 = M 1 M 2 = M 1 V 1 / V 2 M 2 = 0.25000 M x 10.00 mL / 250.00 mL M 2 = 0.010000 M

30 QUESTION

31 Answer

32 © Copyright 1995-2010 R.J. Rusay Solution Applications 20.00 mL of a barium chloride solution required 15.50 mL of the potassium sulfate solution to react completely. M K2SO4 = ? 20.00 mL of a M 2 = 0.010000 M barium chloride solution required 15.50 mL of the potassium sulfate solution to react completely. M K2SO4 = ? BaCl 2 (aq) + K 2 SO 4 (aq)  ? + ? BaCl 2 (aq) + K 2 SO 4 (aq)  2 KCl (aq) + BaSO 4 (s) ?M K2SO4 K2SO4 ] [? mol K2SO4 / ? mol BaCl2 ] ?M K2SO4 = [M BaCl2 x V BaCl2 / V K2SO4 ] [? mol K2SO4 / ? mol BaCl2 ] 1 mol K2SO4 0.010000 mol BaCl2 x 0.02000 L BaCl2 x 1 mol K2SO4 L BaCl2 0.01550 L K2SO4 1 mol BaCl2 L BaCl2 x 0.01550 L K2SO4 x 1 mol BaCl2 ?M K2SO4 ?M K2SO4 = ?M K2SO4 0.01290 K2SO4 / L K2SO4 0.01290 K2SO4 ?M K2SO4 = 0.01290 mol K2SO4 / L K2SO4 = 0.01290 M K2SO4

33 © Copyright 1995-2010 R.J. Rusay Solution Applications How many grams of potassium chloride are produced? BaCl 2 (aq) + K 2 SO 4 (aq)  ? + ? BaCl 2 (aq) + K 2 SO 4 (aq)  2 KCl (aq) + BaSO 4 (s) ?g KCl = 0.010000 mol BaCl2 / L BaCl2 x 0.02000 L BaCl2 X 2 mol KCl / 1 mol BaCl2 X 74.55 g KCl /mol KCl 1 0.02982 g KCl = 0.02982 g KCl

34 © Copyright 1995-2010 R.J. Rusay Solution Applications If 20.00 mL of a 0.10 M solution of barium chloride was reacted with 15.00 mL of a 0.20 M solution of potassium sulfate, what would be the theoretical yield of barium sulfate? BaCl 2 (aq) + K 2 SO 4 (aq)  2 KCl (aq) + BaSO 4 (s) BaCl 2 (aq) + K 2 SO 4 (aq)  2 KCl (aq) + BaSO 4 (s) Mol BaCl2 = M BaCl2 x V BaCl2 = 0.10 mol BaCl2 / L BaCl2 x 0.02000 L BaCl2 1 mol BaCl2 = 2.0 x 10 -3 Mol K2SO4 = M K2SO4 x V K2SO4 = 0.20 mol K2SO4 / L K2SO4 x 0.01500 L K2SO4 1 mol K2SO4 = 3.0 x 10 -3 Which is the Limiting Reagent? 2.0 x 10 -3 < 3.0 x 10 -3 2.0 x 10 -3 mol is limiting

35 © Copyright 1995-2010 R.J. Rusay Solution Applications If 20.00 mL of a 0.10 M solution of barium chloride was reacted with 15.00 mL of a 0.20 M solution of potassium sulfate, what would be the theoretical yield of barium sulfate? BaCl 2 (aq) + K 2 SO 4 (aq)  2 KCl (aq) + BaSO 4 (s) BaCl 2 (aq) + K 2 SO 4 (aq)  2 KCl (aq) + BaSO 4 (s) Must use the limiting reagent: 0.10 mol BaCl2 x 0.02000 L BaCl2 x 1 mol BaSO4 x 233.39 g BaSO4 L BaCl2 1 mol BaCl2 mol BaSO4 = = 0.47 g

36 QUESTION

37 ANSWER - 24 242 2 C)2.4 g Remember that the reaction is 2NaOH + HSO  NaSO + 2HO, so there are two moles of NaOH used per one mole of HSO 4.


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