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Chapter 13 Solutions

Chapter 13 Solutions. Types of Mixtures Solutions Suspensions Colloids. A. Solutions. 1. Definitions a. Soluble - capable of being dissolved b. Solution - homogeneous mixtures 2. Nature of Solutions a. Solvent - dissolving medium b. Solute - substance dissolved

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Chapter 13 Solutions

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  1. Chapter 13 Solutions

  2. Types of MixturesSolutionsSuspensionsColloids

  3. A. Solutions 1. Definitions a. Soluble - capable of being dissolved b. Solution - homogeneous mixtures 2. Nature of Solutions a. Solvent - dissolving medium b. Solute - substance dissolved c. Electrolytes vs. nonelectrolytes

  4. 3. Properties of Solutions a. Particle type - ions, atoms, small molecules b. Particle size - 0.1 - 1 nm c. Effect of light - no scattering d. Effect of gravity - stable e. Filtration - cannot be separated f. Uniformity- Homogeneous

  5. 4. Types of Solutions a. Gaseous solutions b. Liquid solutions c. Solid solutions (alloys) solute solvent example oxygen nitrogen air mixture water drops air humid day gold silver 14k gold

  6. B. Suspensions 1. Definition - heterogeneous mixture 2. Properties a. Particle type: large particles or aggregates b. Particle size: 100 nm and larger c. Effect of light: gives Tyndall effect

  7. d. Effect of gravity: unstable e. Filtration: can be separated f. Uniformity: heterogeneous

  8. C. Colloids 1. Definition: mixture between a solution and a suspension 2. Properties a. Particle type: large molecule or particle b. Particle size: 1 - 100 nm

  9. c. Effect of light: gives Tyndall effect d. Effect of gravity: stable e. Filtration: cannot be separated f. Uniformity: borderline

  10. Tyndall Effect

  11. Is solute ionic compd or moelcular compound? Dissolve solute in water and check if solution will conduct electricity Ionic compound in aqueous form will conduct electricity, due to ions ability to carry charge – electrolyte Ex. NaCl(aq) will conduct electricity

  12. Molecular compound dissolved in water will not conduct electricity, because molecules are neutral – nonelectrolytes. Ex. Sugar, C12H22O11 dissolved in water will not conduct electricity.

  13. The Solution Process A. Factors Affect Rates of Dissolving 1. Surface area - smaller is faster 2. Agitation - stirring/shaking is faster 3. Heat a. Liquids and solids - increase in heat mostly increases rate b. Gases - increase in heat decreases rate

  14. 4. Pressure a. Liquids - no affect b. Gases - increase pressure increase rate

  15. B. Solubility 1. Saturated - maximum amount of dissolved solute 2. Unsaturated - less solute than saturated 3. Supersaturated - more dissolved solute than saturated

  16. 4. Definitions: a. Solution equilibrium - physical state in which the opposing processes of dissolving and crystallizing occur at an equal rate b. Solubility - amount of substance required to form a saturated solution with a specific amount of solvent at a specified temperature

  17. Solubility Table

  18. C. Factors Affecting Solubility 1. Types of solvents and solutes a. “like dissolves like” – • polar molecules will dissolve polar molecules and ionic compds due to attractions of opposite poles. • Nonpolar molecules will dissolve nonpolar molecules b. miscible and immiscible

  19. 2. Pressure a. Liquids and solids - little to no effect b. Gases - solubility increases with increase pressure • Henry’s law - solubility of a gas in a liquid is directly proportional to the partial pressure of that gas on the surface of the liquid • Example: CO2 stays dissolved in soda with a pressure of over 5 atm.

  20. 3. Temperature a. Liquids and solids - increase temperature increases solubility (mostly) b. Gases - increase temperature decreases solubility

  21. D. Heats of Solution 1. Definitions a. Heat of solution - amount of heat energy absorbed or released when a solute dissolves in a specific amount of solvent b. Endothermic - positive heat of solution

  22. c. Exothermic - negative heat of solution d. Solvated - a solute molecule is surrounded by solvent molecules

  23. 2. Solution formation a. Solute-solute broken up: requires energy b. Solvent-solvent broken up: requires energy c. Solute-solvent attraction: releases energy 3. Positive heat of solution (endothermic) when a + b > c 4. Negative heat of solution (exothermic) when a + b < c

  24. III. Concentration of Solutions Concentration of solutions – amt of solute in given amt of solvent or solution Universal solvent is water if not mentioned in the problem.

  25. A. % by Mass • number of grams of solute dissolved in 100 g of solution#g of solute X 100 g solution Example: What is the % by mass of a solution prepared by dissolving 4.0 g HC2H3O2 in 35 g H20?

  26. B. Molarity • Number of moles of solute in one liter of solution M = moles of solute L of solution • Example: What is the molarity of a solution composed of 5.85 g KI dissolved in enough water to make a 125 mL solution?

  27. Ex. How would prepare 1.00 L of 0.500 M CuSO4 · 5H2O solution? Give clear directions.

  28. C. Molality • Number of moles solute per kilogram of solvent m = moles solute kg of solvent • Example: How many grams of AgNO3 are needed to prepare a 0.125 m solution in 250 g of water?

  29. IV. Colligative Properties of Solutions A. Definition - a property that depends on the number of solute particles but is independent of their nature 1. Nonelectrolytes - 1 solute particle 2. Electrolytes - # of solute particles dependent on # ions NaCl: 2 AgNO3: 2 MgCl2: 3 K3PO4: 4

  30. B. Types of Colligative Properties 1. Vapor Pressure Lowering - the tendency for molecules to escape from a liquid to a gas is less in a solution than a pure solvent

  31. 2. Freezing Point – solution has a lower fp than solvent Explanation: when solute is added to solvent, the solute particles interfere with the solvent particles from coming togetheras a solid so the temp is lowered to get the solution to freeze. Illustrate.

  32. The amount of decrease in freezing temperature when a solute is dissolved is called freezing point depression, Δtf = Kfm Δtf=freezing point change= orig. f.p.– new f.p. Kf=molal freezing point constant m = molality of the solution • Example: What is the fp of water in a solution of 17.12 g C12H22O11 and 200 g of water?

  33. 3. Boiling Point – solution has a higher bp than solvent Explanation: When solute is added to solvent, the solute particles interfere with the solvent particles from boiling up so the temp is raised to get the solution to boil. Illustrate.

  34. The amount of increase in boiling temperature when a solute is dissloved is called boiling point elevation, Tb Δ tb = Kbm Δtb = change bp Kb = molal boiling pt constant m = molality Example: What is the bp of a solution that is made by adding 20 g C12H22O11 in 500g H20?

  35. C. Determination of Molar Mass of a Solute 1. Determine Δtf(Δ tb) 2. Determine m Δt = Km 3. If ionic divide by number of particles 4. Calculate moles of solute m X kg of solvent 5. Molar mass = mass of solute moles of solute

  36. Example: When 1.56 g of an unknown , nonvolatile solute is dissolved in 200 g H2O, the Δtf = -0.453 Co. Determine the molar mass.

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