Acids & Bases Svante Arrhenius (1887)

1. Acids & BasesSvante Arrhenius (1887) • ACIDS • Turn indicator dye litmus from blue to red • React with active metals such as zinc, iron, and tin, dissolving the metal and producing hydrogen gas • Taste sour, if diluted enough to be tasted safely • React with certain compounds called alkalis or bases to form water and compounds called salts • BASES • Turn the indicator dye litmus from red to blue • Feel slippery or soapy on the skin • Taste bitter • React with acids to form water and salts

2. Acids • Arrhenius proposed that these characteristic properties of acids are actually properties of the hydrogen ion (H+), and that acids are compounds that yield H+ in aqueous solutions. • Slightly modified today • Hydronium ion (H3O+) • For simplification, we’ll stick with the H+ terminology.

3. Acids • Monoprotic • One H+ • Diprotic • Two H+ • Triprotic • Three H+ • Polyprotic • General term for acids that give up more than one H+ • Strong Acids • Ionize completely (or nearly completely) in water • HCl (hydrochloric acid) • Weak Acids • Ionize only slightly in water • CH3COOH (acetic acid)

4. Bases • Yield hydroxide ions (OH-) in aqueous solutions • Monobasic • One hydroxyl anion • Dibasic • Two hydroxyl anions • Tribasic • Three hydroxyl anions • Polybasic • General term for bases that give up more than one OH- • Strong Bases • Completely ionize • NaOH (sodium hydroxide; lye) • All the bases of Group I and Group II are strong bases • Weak Bases • NH3 (ammonia)

5. pH Scale • pH = -log [H+]

6. Brønsted-Lowry Acid-Base Theory • By the 1920’s chemists were working with solvents other than water. • Acid • Proton (H+) donor • Base • Proton (H+) acceptor

7. Acid-Base Titrations • Method used to determine just how much acid (or base) there is in a solution of unknown concentration • Burette • A piece of laboratory glassware designed to deliver known amounts of liquid into another container

8. Acid-Base Titrations • One mole of NaOH will react completely with one mole of H+ • Using volumetric analyses with a pH indicator, you can determine the moles of H+

9. A Word About Moles…. • A mole used in chemistry is something like the dozen we use every day. • A mole simply means that you have 6.02 x 1023 of whatever you’re talking about. • Avogardo’s number • Molarity is defined as the number of moles of solute divided by the number of liters of solution • Molarity (M) = moles of solute • liters of solution

10. Water Hardness • Calcium (Ca2+) • Magnesium (Mg2+) • Why the concern?

11. Types of Water Hardness • Temporary • Permanent

13. EDTA • Ethylenediaminetetracetic acid • Chelating agent

14. Eriochrome Black T (EBT)

15. Example Calculations • 50.0 mL sample of tap water analyzed • Beginning volume of EDTA = 22.57 mL • End volume of EDTA = 6.23 mL • Amount of EDTA titrated = 16.34 mL • Questions: • How many moles of EDTA were used? • What is the molarity of metal ion present in the water? • What is the concentration of CaCO3 in ppm in the water?

16. How many moles of EDTA were titrated? Molarity of EDTA = 0.01000 M Moles of EDTA = (Molarity)(Liters of solution) = (0.01000 mol/L)(0.01634 L) = 0.0001634 moles EDTA = 1.634 x 10-4 moles EDTA

17. What is the molarity of the metal ion present in the water? Molarity of metal ion = moles of EDTA liters of water sample = 0.00001634 mol EDTA 0.050 L water = 0.003268 mol/L of EDTA = 0.003268 mol/L metal ions

18. What is the concentration of CaCO3 in ppm in the water? CaCO3 ppm = Molarity of metal ion X molecular weight of Ca2+ X 1000 mg/g CaCO3 ppm = 0.003268 mol/L X 40.08 g/mol X 1000 mg/g CaCO3 ppm = 131 mg/L = 131 ppm