Ch. 13 & 14 - Solutions I I. The Nature of Solutions II III (p. 401 - 410, 425 - 433) C. Johannesson A. Definitions Solution - homogeneous mixture Solute - substance being dissolved Solvent - present in greater amount C. Johannesson A. Definitions Solute - KMnO4 C. Johannesson Solvent - H2O B. Solvation Solvation – the process of dissolving solute particles are surrounded by solvent particles solute particles are separated and pulled into solution C. Johannesson B. Solvation - - + sugar - + + salt acetic acid NonElectrolyte Weak Electrolyte Strong Electrolyte solute exists as molecules only solute exists as ions and molecules solute exists as ions only View animation online. C. Johannesson DISSOCIATION IONIZATION B. Solvation “Like Dissolves Like” NONPOLAR POLAR NONPOLAR POLAR C. Johannesson B. Solvation Soap/Detergent • polar “head” with long nonpolar “tail” • dissolves nonpolar grease in polar water C. Johannesson C. Solubility UNSATURATED SOLUTION more solute dissolves SATURATED SOLUTION no more solute dissolves concentration C. Johannesson SUPERSATURATED SOLUTION becomes unstable, crystals form C. Solubility Solubility • maximum grams of solute that will dissolve in 100 g of solvent at a given temperature • varies with temp • based on a saturated soln C. Johannesson C. Solubility Solubility Curve • shows the dependence of solubility on temperature C. Johannesson C. Solubility Solids are more soluble at... • high temperatures. Gases are more soluble at... • low temperatures & • high pressures (Henry’s Law). • EX: nitrogen narcosis, the “bends,” soda C. Johannesson Ch. 13 & 14 - Solutions I II. Concentration II III (p. 412 - 418) C. Johannesson A. Concentration The amount of solute in a solution. Describing Concentration • % by mass - medicated creams • % by volume - rubbing alcohol • ppm, ppb - water contaminants • molarity - used by chemists • molality - used by chemists C. Johannesson B. Molality moles of solute molality (m) kg of solvent 0.25 mol 0.25m 1 kg mass of solvent only 1 kg water = 1 L water C. Johannesson C. Dilution Preparation of a desired solution by adding water to a concentrate. Moles of solute remain the same. M1V1 M 2V2 C. Johannesson D. Preparing Solutions 1.54m NaCl in 0.500 kg of water • mass 45.0 g of NaCl • add 0.500 kg of water 500 mL of 1.54M NaCl • mass 45.0 g of NaCl • add water until total volume is 500 mL 500 mL water 500 mL mark 45.0 g NaCl C. Johannesson 500 mL volumetric flask D. Preparing Solutions Copyright © 1995-1996 NT Curriculum Project, UW-Madison (above: “Filling the volumetric flask”) C. Johannesson D. Preparing Solutions Copyright © 1995-1996 NT Curriculum Project, UW-Madison (above: “Using your hand as a stopper”) C. Johannesson D. Preparing Solutions 250 mL of 6.0M HNO3 by dilution 95 mL of 15.8M HNO3 • measure 95 mL of 15.8M HNO3 • combine with water until total volume is 250 mL 250 mL mark • Safety: “Do as you oughtta, add the acid to the watta!” water for safety C. Johannesson Solution Preparation Lab Turn in one paper per team. Complete the following steps: A) Show the necessary calculations. B) Write out directions for preparing the solution. C) Prepare the solution. For each of the following solutions: 1) 100.0 mL of 0.50M NaCl 2) 0.25m NaCl in 100.0 mL of water 3) 100.0 mL of 3.0M HCl from 12.1M concentrate. C. Johannesson Ch. 13 & 14 - Solutions I III. Colligative Properties II III (p. 436 - 446) C. Johannesson A. Definition Colligative Property • property that depends on the concentration of solute particles, not their identity C. Johannesson B. Types Freezing Point Depression (tf) • f.p. of a solution is lower than f.p. of the pure solvent Boiling Point Elevation (tb) • b.p. of a solution is higher than b.p. of the pure solvent C. Johannesson B. Types Freezing Point Depression View Flash animation. C. Johannesson B. Types Boiling Point Elevation Solute particles weaken IMF in the solvent. C. Johannesson B. Types Applications • salting icy roads • making ice cream • antifreeze • cars (-64°C to 136°C) • fish & insects C. Johannesson C. Calculations t = k · m · n t: change in temperature (°C) k: constant based on the solvent (°C·kg/mol) m: molality (m) n: # of particles C. Johannesson C. Calculations # of Particles • Nonelectrolytes (covalent) • remain intact when dissolved • 1 particle • Electrolytes (ionic) • dissociate into ions when dissolved • 2 or more particles C. Johannesson C. Calculations At what temperature will a solution that is composed of 0.73 moles of glucose in 225 g of phenol boil? GIVEN: WORK: b.p. = ? m = 0.73mol ÷ 0.225kg tb = ? tb = (3.60°C·kg/mol)(3.2m)(1) kb = 3.60°C·kg/mol tb = 12°C m = 3.2m b.p. = 181.8°C + 12°C n=1 b.p. = 194°C tb = kb · m · n C. Johannesson C. Calculations Find the freezing point of a saturated solution of NaCl containing 28 g NaCl in 100. mL water. GIVEN: f.p. = ? tf = ? kf = 1.86°C·kg/mol WORK: m = 0.48mol ÷ 0.100kg tf = (1.86°C·kg/mol)(4.8m)(2) m = 4.8m n=2 tf = kf · m · n f.p. = 0.00°C - 18°C tf = 18°C f.p. = -18°C C. Johannesson Ch. 15 & 16 - Acids & Bases I. Introduction to Acids & Bases I II (p. 453 - 473) III C. Johannesson A. Properties electrolytes sour taste turn litmus red react with metals to form H2 gas vinegar, milk, soda, apples, citrus fruits C. Johannesson electrolytes bitter taste turn litmus blue slippery feel ammonia, lye, antacid, baking soda ChemASAP B. Definitions Arrhenius - In aqueous solution… • Acids form hydronium ions (H3O+) HCl + H2O + H3O H H Cl acid C. Johannesson O H H – + O H + Cl H – Cl B. Definitions Arrhenius - In aqueous solution… • Bases form hydroxide ions (OH-) NH3 + H2O + NH4 H H H N H base C. Johannesson O H H – + O N H + OH H H H B. Definitions Brønsted-Lowry • Acids are proton (H+) donors. • Bases are proton (H+) acceptors. HCl + H2O acid – Cl + + H3O base conjugate base C. Johannesson conjugate acid B. Definitions H2O + HNO3 H3O+ + NO3– B C. Johannesson A CA CB B. Definitions NH3 + H2O B A Amphoteric C. Johannesson + NH4 CA + OH CB - can be an acid or a base. B. Definitions Give the conjugate base for each of the following: HF F H3PO4 H2PO4 + H3O H2O Polyprotic C. Johannesson - - an acid with more than one H+ B. Definitions Give the conjugate acid for each of the following: Br C. Johannesson - HBr HSO4 H2SO4 2CO3 HCO3 B. Definitions Lewis • Acids are electron pair acceptors. • Bases are electron pair donors. Lewis base C. Johannesson Lewis acid C. Strength Strong Acid/Base • 100% ionized in water • strong electrolyte HCl HNO3 H2SO4 HBr HI HClO4 C. Johannesson - + NaOH KOH Ca(OH)2 Ba(OH)2 C. Strength Weak - + Acid/Base • does not ionize completely • weak electrolyte HF CH3COOH H3PO4 H2CO3 HCN C. Johannesson NH3 Ch. 15 & 16 - Acids & Bases I II. pH II III (p. 481 - 491) C. Johannesson A. Ionization of Water H 2O + H 2 O Kw = H3 + [H3O ][OH ] C. Johannesson + O + = 1.0 OH -14 10 A. Ionization of Water Find the hydroxide ion concentration of 3.0 10-2 M HCl. [H3O+][OH-] = 1.0 10-14 [3.0 10-2][OH-] = 1.0 10-14 [OH-] = 3.3 10-13 M Acidic orAcidic basic? C. Johannesson B. pH Scale 14 0 7 INCREASING ACIDITY pH = NEUTRAL + -log[H3O ] pouvoir hydrogène (Fr.) “hydrogen power” C. Johannesson INCREASING BASICITY B. pH Scale pH of Common Substances C. Johannesson B. pH Scale pH = + -log[H3O ] pOH = -log[OH ] pH + pOH = 14 C. Johannesson B. pH Scale What is the pH of 0.050 M HNO3? pH = -log[H3O+] pH = -log[0.050] pH = 1.3 Acidic orAcidic basic? C. Johannesson B. pH Scale What is the molarity of HBr in a solution that has a pOH of 9.6? pH + pOH = 14 pH = -log[H3O+] pH + 9.6 = 14 4.4 = -log[H3O+] pH = 4.4 -4.4 = log[H3O+] Acidic [H3O+] = 4.0 10-5 M HBr C. Johannesson Ch. 15 & 16 - Acids & Bases I III. Titration II III (p. 493 - 503) C. Johannesson A. Neutralization Chemical reaction between an acid and a base. Products are a salt (ionic compound) and water. C. Johannesson A. Neutralization ACID + BASE SALT + WATER HCl + NaOH NaCl + H2O strong strong neutral HC2H3O2 + NaOH NaC2H3O2 + H2O weak strong basic • Salts can be neutral, acidic, or basic. • Neutralization does not mean pH = 7. C. Johannesson B. Titration standard solution Titration • Analytical method in which a standard solution is used to determine the concentration of an unknown solution. unknown solution C. Johannesson B. Titration Equivalence point (endpoint) • Point at which equal amounts of H3O+ and OHhave been added. • Determined by… • indicator color change • dramatic change in pH C. Johannesson B. Titration + O moles H3 = moles MVn = MVn OH M: Molarity V: volume n: # of H+ ions in the acid or OH- ions in the base C. Johannesson B. Titration 42.5 mL of 1.3M KOH are required to neutralize 50.0 mL of H2SO4. Find the molarity of H2SO4. H3O+ OH- M=? M = 1.3M V = 50.0 mL n=2 V = 42.5 mL n=1 C. Johannesson MV# = MV# M(50.0mL)(2) =(1.3M)(42.5mL)(1) M = 0.55M H2SO4