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William L Masterton Cecile N. Hurley http://academic.cengage.com/chemistry/masterton Edward J. Neth University of Connecticut Chapter 4 Reactions in Aqueous Solution
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Outline Solute Concentrations: Molarity Precipitation Reactions Acid-Base Reactions Oxidation-Reduction Reactions
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Review In Chapter 3, we learned about chemical reactions Most reactions were between pure gases, liquids and solids No solvent was used
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Background: 1. Many reactions occur in aqueous solutions: Three common types of reactions in solution: Precipitation, Acid-base, and Oxidation-reduction Concentration of solutions is measured in units of Molarity Water is the universal solvent
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2. Definitions Solution: homogeneous mixture of a solvent and a solute (not always in same phase – solid/liquid/gas) Aqueous: dissolved in water Anion: a negatively charged ion Ex O 2-, CN -1 Cation: positively charged ion Ex H + Electrodes: measure “electron” flow in a solution
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Solute Concentrations - Molarity Definition of molarity Molarity = moles of solute/liters of solution Symbol is M Square brackets are used to indicate concentration in M [Na + ] = 1.0 M Example: 1.5 moles of NaCl are dissolved to make 250mL aqueous solution.
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Additivity Masses are additive; volumes are not The total mass of a solution is the sum of the mass of the solute and the solvent The total volume of a solution is not the sum of the volumes of the solute and solvent Molarity as a conversion: Use: # moles = 1 Liter
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Volumetric Glassware Volumetric pipets, burets and flasks are made so that they contain an exact volume of liquid at a given temperature Preparing solutions with concentrations in M involves using volumetric glassware
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Figure 4.1 – Preparation of Molar Solution
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Example 4.1
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Dissolving Ionic Solids When an ionic solid is dissolved in a solvent, the ions separate from each other MgCl 2 (s) → Mg 2+ (aq) + 2 Cl -1 (aq) The concentrations of ions are related to each other by the formula of the compound: Molarity of MgCl 2 = Molarity of Mg 2+ Molarity of Cl -1 = 2 X Molarity of MgCl 2 Total number of moles of ions per mole of MgCl 2 is 3
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Example 4.2
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Solubility: Soluble compounds that dissolve Insoluble compounds that do not dissolve
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Precipitation Precipitation in chemical reactions is the formation of a solid where no solid existed before reaction Precipitation is the reverse of solubility, where a solid dissolves in a solvent to produce a solution
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Precipitates Precipitates are called insoluble – they do not dissolve in solution Precipitation of an insoluble solid Mix a solution of nickel(II) chloride with one of sodium hydroxide A solid forms: Ni(OH) 2 (s)
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Figure 4.4
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Figure 4.3 – Precipitation Diagram
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Solubility Trends Mostly soluble Compounds of Group 1 and NH 4 + cations All nitrates All chlorides, except for AgCl All sulfates, except for BaSO 4
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Solubilities Trends Mostly insoluble Carbonates and phosphates, except for the Group I and ammonium Hydroxides, except for the Group 1, Group 2 and ammonium
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Simple Solubility Rules: SAP (compounds containing sodium, ammonium, and potassium are soluble) CAN (chlorate, acetate, and nitrate containing compounds are soluble)
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Example 4.3
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Net Ionic Equations Consider the precipitation of CaCO 3 from solutions of CaCl 2 and Na 2 CO 3 Formula Equ. Ioinic Equ. Net Ionic Equ.
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Spectator Ions: ions that remain soluble on the products side of the reaction Net ionic equations - follow the rules for equations Atoms must balance Charges must balance Show only the ions that react
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Example 4.4
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Example 4.5 - Precipitation Stoichiometry
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Acids and Bases Everyday life includes contact with many acids and bases
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Strong and Weak Acids and Bases Strong acids ionize completely to H + HCl (aq) → H + (aq) + Cl - (aq) In a solution of 1.0 M HCl, there is 1M H + and 1M Cl - No HCl is left un-ionized Other strong acids ionize in similar fashion
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Weak Acids Weak acids ionize only partially HB (aq) ⇌ H + (aq) + B - (aq) HF (aq) ⇌ H + (aq) + F - (aq) Commonly, weak acids are 5% ionized or less; double headed arrow means the reaction is moving in both directions
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Strong Bases Strong bases ionize completely to OH - NaOH (s) → Na + (aq) + OH - (aq) Ca(OH) 2 → Ca 2+ (aq) + 2 OH - (aq)
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Strong Acids and Bases
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Weak Bases Weak bases ionize only partially NH 3 (aq) + H 2 O ⇌ NH 4 + (aq) + OH - (aq) CH 3 NH 2 (aq) + H 2 O ⇌ CH 3 NH 3 + (aq) + OH - (aq) Commonly, weak bases are 5% ionized or less
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Strong Acid – Strong Base Reactions: Neutralization Reaction: Double replacement reaction, one product will always be water; best to write as H(OH) Example: H 2 SO 4 + NaOH
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Strong Acids and Bases: Must be memorized: Strong Acids: Br I Cl SO NO ClO 4,3,4 Strong Bases: hydroxides of group I except the first 1(H) and group II except the first 2(Be and Mg)
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Example 4.6
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Acid-Base Titrations Commonly used to determine the Molarity of a solution
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Titrations Titrant (in the buret) Know concentration Know volume Analyte (in the Erlenmeyer flask) Know volume or mass Unknown concentration
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Titrations Indicator: Dye solution that changes color at a set pH Equivalence Point: the place in the titration where the number of moles of acid and moles of base in the flask are equal Endpoint: the place in the titration where the color changes
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Figure 4.7 – An Acid-Base Titration
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Example 4.7
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Acids and Metals Many metals will react with acids, producing hydrogen gas
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Oxidation-Reduction Reactions Short name: Redox reactions Electron exchange Oxidation is a loss of electrons; increase charge Reduction is a gain of electrons; decrease charge
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Reaction of Zinc with an Acid Zn (s) + 2 H + (aq) → Zn 2+ (aq) + H 2 (g) Consider two half equations: Zn loses two electrons Zn (s) → Zn 2+ (aq) + 2 e - H + gains an electron 2H + (aq) + 2 e - → H 2 (g)
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Principles: Oxidation and reduction must occur together The total number of electrons on each side of the equation must be equal; no net change
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Cause and Effect Something must cause the zinc to lose two electrons This is the oxidizing agent – the H + Something must cause the H + to gain two electrons This is the reducing agent – the Zn
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Reducing Agents Reducing agents become oxidized We know that metals commonly form cations Metals are generally reducing agents
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Oxidizing Agents We know that many nonmetals form anions To form an anion, a nonmetal must gain electrons Many nonmetals are good oxidizing agents
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Rules Governing Oxidation Numbers 1. The oxidation number of an element that is alone (including diatomic elements) is zero. 2. The oxidation number of a element in a monatomic ion is the charge on the ion 3. Certain elements have the same oxidation number in most compounds a.Group 1 metals are +1 b.Group 2 metals are +2 c.Oxygen is always -2 d.Hydrogen is always +1 4. Oxidation numbers sum to zero (compound) or to the charge (polyatomic ion)
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Example 4.8
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Redox Reactions and Oxidation Numbers Oxidation is an increase in oxidation number This is the same as a loss of electrons (LEO) Reduction is a decrease in oxidation number This is the same as a gain of electrons (GER)
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Example: Which element is being oxidized and which is being reduced? Fe Fe +2 + 2e- F + 1e- F -1
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