<p>A c i d s & B a s e s N o t e s P a g e | 1</p><p>Unit 12: Acids & Bases (Link to Prentice Hall Text: Chapters 20 & 21)</p><p>Name:______</p><p>Date Due Assignments Page Number: Problem Numbers</p><p>Assignment 1: Naming Acids/Bases 609: 34</p><p>Assignment 2: Conjugate Acid/Bases and Definitions 609: 45, 46, 48, 49, 60, 61</p><p>Assignment 3: Strong/Weak Acids/Bases 609: 52, 53 640: 49</p><p>Assignment 4: Acid/Base Reactions 640: 37, 62</p><p>Assignment 5: Normality 640: 43, 44abc, 60</p><p>Assignment 6: pH Calculations of Strong Acids/Bases 609: 39, 40, 41, 42</p><p>Assignment 7: pH Calculations of Weak Acids/Bases 609: 55, 56, 57, 58, 59, 62</p><p>Assignment 8: Titration Calculations 640: 45 A c i d s & B a s e s N o t e s P a g e | 2</p><p>Names of Acids & Bases</p><p>Rules for Naming Acids</p><p>1. Binary Acids (only Hydrogen and one other element present) a. Hydro + root + ic + acid b. Example: HCl = </p><p>2. Polyatomic Acids (Hydrogen and polyatomic ion) a. Name is based on polyatomic ion (Table E) b. If ion ends with “ite” change to “ous” + acid c. If ion ends with “ate” change to “ic” + acid</p><p> d. Example: H2CO3 = </p><p>Rules for Naming Strong Bases</p><p>1. Keep the name of the cation and add hydroxide</p><p>2. Example: Ca(OH)2 = </p><p>Naming Acids & Bases</p><p>Name the following acids and bases.</p><p>1. HBr______14. Hydroiodic acid______</p><p>2. HI______15. Chloric acid______</p><p>3. HF______16. Nitric acid______</p><p>4. H3PO4______17. Nitrous acid______</p><p>5. HClO2______18. Bromic acid______</p><p>6. H2SO4______19. Phosphoric acid______</p><p>7. HNO3______20. Hydrosulfuric acid______</p><p>8. HC2H3O2______21. Sulfuric acid______</p><p>9. HNO2______22. Sulfurous acid______</p><p>10. KOH______23. Chlorous acid______</p><p>11. LiOH______24. Perchloric acid______</p><p>12. Ca(OH)2______25. Hydrofluoric acid______</p><p>13. Hypochlorous acid______A c i d s & B a s e s N o t e s P a g e | 3</p><p>A. Three Theories of Acids and Bases</p><p>Arrhenius Theory of Acids and Bases</p><p>Acids and bases can be defined in terms of what ions are released when they are dissolved in water.</p><p>Acids: Release H + when dissolved in water. + - 1. Example: HCl (g)  H (aq) + Cl (aq)</p><p>+ + 2. BUT: H does not exist alone in natures so it combines with the lone pair electrons in H2O to make H3O </p><p>+ – 3. Therefore: HCl (g) + H2O (l)  H3O (aq) + Cl (aq)</p><p>+ 4. The properties of an acid therefore depend on the [H3O ]</p><p>Categories of Arrhenius Acids 1. Monoprotic – </p><p>+ – ex. HCl (g) + H2O (l)  H3O (aq) + Cl (aq) 2. Diprotic – </p><p>+ 2- ex. H2SO4 + 2H2O (l)  2H3O (aq) + SO4 (aq) 3. Triprotic – </p><p>+ 3- ex. H3PO4 + 3H2O (l)  3H3O (aq) + PO4 (aq) </p><p>Bases: Release OH - when dissolved in water.</p><p>+ - 1. NaOH (s)  Na (aq) + OH (aq)</p><p>2. KOH (s)  K+ (aq) + OH- (aq)</p><p>3. Ca(OH)2 (s)  ______+ ______A c i d s & B a s e s N o t e s P a g e | 4</p><p>Brønsted-Lowry Acids and Bases</p><p>Acids and bases can be defined by the ability to donate or accept protons (H + ions). Reactions may not occur in solution phase only.</p><p>Acids: Donate protons.</p><p>Bases: Accept protons. </p><p>Example: HCl (g) + NH3 (g)  NH4Cl (s)</p><p>Lewis Acids and Bases</p><p>Acids and bases can be defined by the ability to donate or accept electron pairs.</p><p>Acids: Electron pair receivers. </p><p>Bases: Electron pair donors.</p><p>Example: NH3 + BF3  NH3BF3</p><p>B. Conjugate Acid-Base Pairs</p><p>Acids and Bases Come in Pairs</p><p>Conjugate Base: Species that exists after a Brønsted-Lowry acid has donated a proton. This species can now accept a proton.</p><p>Conjugate Acid: Species that exists after a Brønsted-Lowry base has accepted a proton. This species can now donate a proton.</p><p> IMPORTANT: Water is amphoteric, that is, it can act as both a Brønsted-Lowry acid or base depending on what else is in solution. The reaction of water and another acid or base is called hydrolysis. A c i d s & B a s e s N o t e s P a g e | 5</p><p>Practice Identifying Conjugate Acid-Base Pairs</p><p>Identify the acid(A), base(B), conjugate acid (CA), and conjugate base (CB) in each of the equations.</p><p>+ – – – 2– 1. HCl + NH3 → NH4 + Cl 5. HCO3 + OH → H2O + CO3</p><p>– – + + 2. OH + HCN → H2O + CN 6. NH4 + H2O → NH3 + H3O</p><p>3– – 2– 2– – – 3. PO4 + HNO3 → NO3 + HPO4 7. C2O4 + HC2H3O2 → HC2O4 + C2H3O2</p><p>– – 2– – – 4. HCO3 + HCl → H2CO3 + Cl 8. HPO4 + H2O → OH + H2PO4</p><p>Fill in the blanks in the table below. When you write the chemical equation, show the reaction for the hydrolysis of the acid (reacting the acid with water) for 1-5 and the reaction for the hydrolysis of the base (reacting the base with water) for 6-10.</p><p>Conjugate ACID Conjugate BASE Hydrolysis of Acid</p><p>1. H2SO4</p><p>2. H3PO4 3. F-</p><p>- 4. NO3</p><p>- 5. H2PO4 Hydrolysis of Base</p><p>2- 6. SO4</p><p>2- 7. HPO4</p><p>8. H2O</p><p>+ 9. NH4</p><p>10. H2O A c i d s & B a s e s N o t e s P a g e | 6</p><p>C. Identification of Strong/Weak Acids, Bases & Neutral Salts</p><p>Strong vs. Weak</p><p>Identifying S/W Acids & Bases and Neutral Salts A. Strong Acids </p><p> Strong acids = </p><p> Seven strong acids: HNO3, H2SO4, HCl, HBr, HI, HClO4, & HClO3</p><p>B. Weak Acids  Weak acids = </p><p> Any formula with an H written in the front of the compound and is not strong, is considered weak. </p><p>C. Strong Bases  Strong Bases =  Hydroxide ion bonded with Group I or I or the bottom half of Group II metals form strong bases.</p><p>D. Weak Bases  Weak bases = </p><p> The conjugate base of a weak acid is a weak base.  Weak bases are typically conjugate bases of weak acids (negatively charged) or substances that contain a nitrogen atom with a lone pair (amines).  You may see a weak base written as a negative ion alone, or it may be “’disguised” as a salt. A c i d s & B a s e s N o t e s P a g e | 7</p><p>E. Neutral Salts Practice Identifying Acidic/Basic/Neutral Substances</p><p>Substance S/W A/B or N? Net Ionic Equation for Hydrolysis of Substance</p><p>1. H2SO4</p><p>2. NaOH</p><p>3. HC2H3O2</p><p>4. KC2H3O2</p><p>5. CH3CH2NH2</p><p>2- 6. CO3</p><p>7. NaCl</p><p>8. KF</p><p>9. HCN</p><p>10. Ca(OH)2</p><p>11. HClO4</p><p>12. LiBr</p><p>13. NaClO3</p><p>14. KNO2</p><p>15. NH3</p><p>16. H2CO3</p><p>17. LiCN</p><p>18. CH3NH2</p><p>2- 19. SO3</p><p>3- 20. PO4</p><p>21. (amphoteric) (a) (a) 2- HPO4 (b) (b) A c i d s & B a s e s N o t e s P a g e | 8</p><p>D. Chemical Reactions of Acids & Bases</p><p>Acid – Metal Reaction (Single Replacement Reaction) 1. Remember: The more active metal gets the partner! Consult Table J. 2. Elements above hydrogen will react with an acid and produce hydrogen gas and a salt.</p><p>3. Examples: Ba (s) + 2HCl (aq)  H2 (g) + BaCl2 (aq)</p><p>4. Practice: Zn + HCl  ______+ ______</p><p>Neutralization Reaction 1. An acid and a base react together to form water and a salt. </p><p>2. Example: HCl (aq) +NaOH (aq)  NaCl (aq) + H2O (l)</p><p>3. Practice: HNO3 (aq) + KOH (aq)  ______+ ______</p><p>Acid/Base Chemical Reaction Practice Write the balanced chemical equation for each of the following reactions.</p><p>1. _____Ca(OH)2 (aq) + _____HNO3 (aq) ______</p><p>2. _____Mg(OH)2 (aq) + _____HCl (aq) ______</p><p>3. _____H3PO4 (aq) + ______Ba(OH)2 (aq) ______</p><p>4. _____Al (s) + _____ HCN (aq) ______</p><p>5. Nitric acid is added to potassium hydroxide. ______</p><p>6. Barium hydroxide and hydrobromic acid are mixed. ______</p><p>7. Sulfuric acid and calcium hydroxide are mixed. ______</p><p>8. Ammonium hydroxide and hydroiodic acid are mixed. ______</p><p>9. Nitric acid and magnesium are mixed. ______</p><p>10. Aluminum and sulfuric acid are mixed. ______</p><p>11. Silver and phosphoric acid are mixed. ______</p><p>12. Zinc and acetic acid are mixed. ______A c i d s & B a s e s N o t e s P a g e | 9</p><p>E. Acid-Base Indicators</p><p>A Reference Table for Indicators Indicators are weak acids or bases that dissociate over a known pH range producing a color change. See Table M in Reference Table for a list of common indicators.</p><p>Cabbage Juice Indicator </p><p>Purpose: To use a home-made indicator to determine the acidity or basicity of a compound.</p><p>Introduction: Red cabbage contains a pigment molecule called flavin (an anthocyanin). This water-soluble pigment is also found in apple skin, plums, cornflowers, and grapes. Very acidic solutions will turn anthocyanin a red color. Neutral solutions result in a purplish color. Basic solutions appear in greenish-yellow. Therefore, it is possible to determine the pH of a solution based on the color it turns the anthocyanin pigments in red cabbage juice. </p><p>Red Cabbage Color Key</p><p> pH 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Color</p><p>Substance Cabbage Juice Color pH Value Table salt (aq)</p><p>Vinegar (aq)</p><p>Rubbing Alcohol</p><p>Lemon juice</p><p>Distilled Water</p><p>Stomach Acid (aq)</p><p>Tums A c i d s & B a s e s N o t e s P a g e | 10</p><p>Practice Determining Indicator Colors Using Table M 1. Which indicator is blue in a neutral solution?</p><p>2. Name an indicator that is yellow at pH 4.</p><p>3. Name an indicator that is yellow at pH 9.</p><p>4. What is the pH of a solution that changes methyl orange indicator yellow and litmus red?</p><p>5. Which indicator appears colorless in HNO3(aq)?</p><p>6. Bromocresol green indicator is added to a beaker containing NaOH(aq). What color change will be observed as HCl is added to the solution in the beaker?</p><p>7. Calcium hydroxide is commonly known as agricultural lime and is used to adjust the soil pH. Before the lime was added to a field, the soil pH was 5. After the lime was added, the soil pH changed to 9.</p><p> a. A small amount of soil is tested with phenolphthalein, what color would the test be before the agricultural lime is added ?</p><p> b. what color would the test be after the agricultural lime is added ? A c i d s & B a s e s N o t e s P a g e | 11</p><p>8. Which indicator, when added to a solution, changes color from yellow to blue as the pH of the solution is changed from 5.5 to 8.0?</p><p>A) Bromocresol green B) Litmus C) Bromothymol blue D) Methyl orange</p><p>9. Which solution will change red litmus to blue?</p><p>A) HCl B) NaCl</p><p>C) C6H12O6 D) NaOH</p><p>10. An acidic solution could have a pH of</p><p>A) 12 B) 3 C) 9 D) 7</p><p>11. Which 0.1 M solution will turn phenolphthalein pink?</p><p>A) HBr</p><p>B) CO2 C) LiOH</p><p>D) CH3OH A c i d s & B a s e s N o t e s P a g e | 12</p><p>F. The pH Scale and pH Calculations with Strong Acids and Bases</p><p>+ - Measuring [H3O ] and [OH ] with the pH Scale pH Equations + + -pH pH = - log[H3O ] [H3O ] = 10 pOH = -log[OH-] [OH-] = 10-pOH pH + pOH = 14 + -  In acids,[H3O ] _____[OH ] + -  In bases, [H3O ]_____[OH ] + -  When neutral, [H3O ]_____[OH ] pH scale 0 7 14 acids neutral bases Practice with pH and pOH Calculations</p><p>- + Acid or Base? pH pOH [OH ] [H3O ] 1. 3.6</p><p>2. 0.01</p><p>-9 3. 1 x 10 M Ca(OH)2</p><p>4. 2.7 x 10-12M</p><p>5. 3.2 x 10-4M HCl 6. 3.2</p><p>7. The original pH of a sample is 7.0. Calculate the new pH if the hydronium ion increases by a factor of 1000.</p><p>8. The original pH of a sample is 12.0. If the hydroxide ion is decreased by a factor of 100, what is the new pH of the sample? A c i d s & B a s e s N o t e s P a g e | 13</p><p>9. The original pH of a sample is 8.00. Calculate the new pH if the hydroxide ion increases by a factor of 10000.</p><p>10. The original pH of a sample is 4.0. If the hydronium ion is decreased by a factor of 100, what is the new pH of the sample? A c i d s & B a s e s N o t e s P a g e | 14</p><p>G. Normality</p><p>Measuring the Extent of Acidity/Basicity with Equivalents Equivalents: The number of moles of H+ or OH- that will be released per mole of acid or base, respectively. For example:</p><p> + + H2SO4 = 2 moles H = 2 equivalents H</p><p>1 mole H2SO4</p><p> Al(OH)3 = </p><p>Measuring the Concentration of Acidity/Basicity with Equivalents Normality Normality, N = Equivalents of H + or OH - Volume (L)</p><p>Practice Determining Normality and Equivalents</p><p>+ 1. How many equivalents of H are in H3PO4?</p><p>- 2. How many equivalents of OH are in Ca(OH)2?</p><p>3. What is the normality of 0.3M phosphoric acid?</p><p>4. What is the normality of 0.60M H2SO4?</p><p>5. What is the normality of 2.5M carbonic acid?</p><p>6. What is the normality of 3.2M HCl? A c i d s & B a s e s N o t e s P a g e | 15</p><p>H. Titration Calculations</p><p>Understanding Titrations and their Corresponding Calculations</p><p>Titration is a procedure used in the lab to determine the unknown concentration of a solution (either acidic or basic) using a known titrant. It is based on the stoichiometry of a neutralization reaction. </p><p>For example: HCl (aq) + NaOH (aq)  H2O (l) + NaCl (aq)</p><p>At the end point or equivalence point (signaled by use of an indicator), there are stoichiometrically equal amounts of titrant and unknown.</p><p>Titration Equation</p><p>NAVA = NBVB</p><p> NA and NB are the normalities of the acid and base solutions.  VA and VB are the volumes of the acid and base solutions.</p><p>Practice with Titration Calculations 1. A 15.00 mL sample of acetic acid is titrated with 34.13 mL of 0.9940 M sodium hydroxide. Determine the molarity of the acetic acid. A c i d s & B a s e s N o t e s P a g e | 16</p><p>1. How much of 0.5M H2SO4 is needed to titrate 25.0mL of 0.05M Ca(OH)2?</p><p>2. A 20.00 mL sample of diluted hydrofluoric acid requires 13.51mL of a 0.1500M calcium hydroxide to be titrated to the equivalence point. What is the molarity of the acid?</p><p>3. A flask contains 41.04mL of potassium hydroxide. The solution is titrated and reaches an equivalence point when 21.65mL of a 0.6515M solution of nitric acid is added. Calculate the molarity of the base solution.</p><p>4. What volume of a 0.5200 M solution of sulfuric acid would be needed to titrate 100.00mL of a 0.1225M solution of strontium hydroxide?</p><p>5. A 50.0 ml sample of sulfuric acid, H2SO4, is titrated with 35.0 ml of 0.250 M aluminum hydroxide, Al(OH)3. Calculate the molarity of the acid. A c i d s & B a s e s N o t e s P a g e | 17</p><p>Calculations of pH & pOH with Weak Acids & Bases Using Ka and Kb</p><p>The Acid and Base Dissociation Constant</p><p>Acid Dissociation Constant, Ka</p><p>+ - + - For the generic reaction: HA (aq) + H2O (l) ↔ H3O (aq) + A (aq) Ka = [H3 O ][A ] [HA]</p><p>Base Dissociation Constant, Kb</p><p>- - - For the generic reaction: A (aq) + H2O (l) ↔ HA (aq) + OH (aq) Kb = [OH ][HA] [A-]</p><p>Practice Determining pH and pOH with Weak Acids and Bases</p><p>–4 + - 1. The acid-dissociation constant for hydrofluoric acid, is 7.08 x 10 . Calculate the concentration of H3O , F and HF at equilibrium if the initial concentration of the acid is 0.2 M. What is the pH and pOH of the solution at equilibrium? A c i d s & B a s e s N o t e s P a g e | 18</p><p>+ - 2. Determine the [H3O ], [OH ], pH, and pOH for each of the following aqueous weak acids.</p><p>-5 a. 1.0M acetic acid (Ka= 1.8 x 10 )</p><p>-4 b. 3.0M nitrous acid (Ka= 4.0 x 10 )</p><p>-5 c. 6.0M Benzoic acid (monoprotic) (Ka= 6.4 x 10 )</p><p>-8 d. 0.01M Hypochlorous acid (Ka= 3.5 x 10 )</p><p>3. Write an equation that shows the reaction when the following acids and bases are hydrolyzed. Use the + information below to determine the concentrations of H3O ions.</p><p>-4 -5 a. A 2.5 x 10 M solution of NH3 (Kb = 1.8 x 10 )</p><p>- -10 b. A 0.5 M solution of C2H3O2 (Kb= 5.6 x 10 ) A c i d s & B a s e s N o t e s P a g e | 19</p><p>-10 c. A 0.01 M solution of HCN (Ka= 6.2 x 10 )</p><p>-4 d. A 6.5 M solution of HF (Ka= 7.2 x 10 )</p>