With enough water molecules, a soluble ionic compound is completely dissolved into aqueous ions

1. With enough water molecules, a soluble ionic compound is completely dissolved into aqueous ions • “Like dissolves like” • Ions become Hydrated • Dissolution of compound • Soluteis written as aqueous ions • Solventis water • Strong electrolytes, ionize completely • Weak electrolytes, • do not dissociate fully weak electricity. Non electrolytes - may dissolve, but do not form ions at all, such as sugar in water, or organic compounds in water.

2. Ionic solids • (or salts) • composed of positive and negative ions, • held together by the strong force of attraction between particles with opposite charges. • ions are released water • solution conducts electricity • new association with the polar solvent molecules. • Why Do Some Solids Dissolve in Water? • sugar - molecular solid, • weak bonds between the individual sucrose molecules are broken, and released into solution. • the bonds within C12H22O11 molecules are not broken. • bonds with-in water molecules are not broken. • Energy is given off when the slightly polar sucrose molecules form intermolecular forces with the polar water molecules. • weak bonds that form between the solute and the solvent compensate for the energy needed to disrupt the structure of both the pure solute and the solvent. • Non-electrolyte because no ions are formed.

3. Soluble compounds are written as Ions include the charge! Insoluble compounds are written as Molecules. • Soluble Compounds • All compounds containing alkali metal ions • compounds containing ammonium ion, NH4+ are soluble • compounds containing • NO3-, ClO4-, ClO3-, and C2H3O2- anions • chlorides, bromides, and iodides are soluble • - except with Ag+, Pb2+, or Hg22+. • sulfates are soluble • - except with Hg22+,Pb2+,Sr2+, Ca2+,Ba2+. • Insoluble Compounds • All hydroxides are insoluble • - except with alkali metals,Ca2+,Sr2+, and Ba2+ • All compounds containing PO43-, S2-, CO32-, and SO32- ions are insoluble • - except with alkali metals or NH4+.

4. Composition of Solutions Molarity = moles of solute liters of solution moles Molarity liters grams Molar mass moles Dilutions; moles in beginning = moles at the end Molarityinitial x volumeinitial = Molarityfinal x volumefinal M1V1=M2V2

5. Molarity Practice Problems • If 500.0 ml of a 1.00M KOH solution and 1500. ml of a 2.00M KOH solution are mixed, and the volume brought up to precisely 2500.0 ml by adding more water, what is the molarity of the final solution. • How many grams of KOH would 250.0 ml of this final solution contain? • When the 250.0 ml of solution above is added to 130.0 ml 2M HCl, how much salt is formed? What is the pH of the resulting solution?

6. Solution Stoichiometry • A 0.350 g sample of solid Barium chloride is added to 125 mL of 0.0100 M Calcium sulfate solution. Assume no change in volume of the solution. • BaCl2(s) + CaSO4 (aq) BaSO4(s) + CaCl2(aq) • List an appropriate observation that provides evidence of a chemical reaction between the two compounds, write the net ionic equation. • Calculate the number of moles of each reactant. • Identify the limiting reactant. Show calculations to support your identification. • (d) Calculate the concentration of aqueous ions in the mixture after the reaction is complete.