Properties of Solutions

Properties of Solutions Solution: Homogenous mixture of 2 or more substances; particles are small (transparent) Colloid: Homogenous mixture of 2 or more substances; particles are larger (opaque) Solutions can be liquid, solid or gaseous Examples: Ocean, sugar water Gold alloy Air, humid oxygen

Solvent: Substance present in a solution in the greatest amount Example: Water in the ocean; nitrogen in air Solute: Substance present in a solution in lesser amounts than the solvent Example: Salt in ocean; oxygen in air Solutes can be electrolytes or nonelectrolytes Electrolytes: solutes that dissociate in solution into ions that carry charge (ionic compounds) Nonelectrolytes: solutes that do not dissociate in solution, and do not carry any charge

Solubility Soluble substance: Substance that is able to dissolve in a solvent Insoluble substance: Substance that does not dissolve in a solvent Solubility: Maximum amount of solute that can be dissolved in a specific amount of solvent under specific conditions of temperature and pressure (g solute/100 mL solution)

Saturated Solution: Solution containing maximum amount of solute that will dissolve under current conditions • Unsaturated Solution: Solution containing less than the maximum amount of solute that will dissolve under current conditions • Supersaturated Solution: Unstable solution containing amount of solute greater than the solubility value

General Rules for the Solubility of Ionic Compounds • A compound is soluble if it contains one of the following cations: • -Group 1A cations: Li+, Na+, K+, Rb+, Cs+ • -Ammonium, NH4+ • A compound is soluble if it contains one of the following anions:

Solubility of Solids and Liquids vs. Gases • Solubility of liquids and solids in water increases with increasing temperature • Example: More sugar will dissolve in warm water than in cold water • Solubility of gases in water decreases with temperature • Solubility of gases in water increases with increasing pressure (Henry’s Law)

“Like dissolves like:” • polar solvents will dissolve polar solutes • nonpolar solvents will dissolve nonpolar solutes • Examples: wax in CCl4, sugar in water; oil in water? • Solutes fail to dissolve when: • 1) forces between solute particles out-weigh attractions between solute and solvent • 2) solvent particles are more attracted to each other than to solute

Examples of Like Dissolves Like SolventsSolutes Water (polar) Ni(NO3)2 (ionic) CH2Cl2 (nonpolar) I2 (nonpolar)

Solutes dissolve faster when: Concentration: Relationship between amount of solute contained in a specific amount of solution • Solute particles are small • Solvent is heated • Solution is stirred

Concentration as Percent • Percent: Solution concentration giving the amount of solute in 100 parts of solution • % = part/total x 100 • Weight/weight percent: Concentration giving the mass of solute in 100 mass units of solution • %(w/w) = solute mass/solution mass x 100 • Example: 12.0%(w/w) sugar solution • 12 g sugar per 100 g solution

Weight/volume percent: Concentration giving the grams of solute contained in 100 mL of solution • %(w/v) = grams solute/mL solution x 100 • Example: 12.0%(w/v) sugar solution • 12 g sugar per 100 mL solution

Molarity: Unit of concentration used with solutions; number of moles of solute per liter of solution • Molarity (M) = moles of solute/liters of solution • Examples: 2 moles of NaCl dissolved in 1 L of water • M = 2 moles/1 L = 2 M • 1.5 moles NaCl dissolved in 2 L of water: • M = 1.50 moles/2.00 L = .750 M

Dilution Dilution: addition of solvent to decrease theconcentration of solute. The solution volume changes,but the amount of solute is constant. moles of solute (mol) = molarity (M) x volume (V) M1V1 = M2V2 initial values final values

M1 V1 =M2 V2 • Practice Problem: Prepare 250 mL of 0.100 M NaCl solution from a 2.00 M NaCl solution. • M1 = molarity of starting solution (in this case 2.00M NaCl) • V1 = volume of starting solution required (always unknown) • M2 = molarity of final solution after dilution (in this case 0.100M NaCl) • V2 = volume of final solution, after dilution (in this case 250ml)

Prepare 250 mL of 0.100 M NaCl solution from a 2.00 M NaCl solution. • M1 = molarity of starting solution (in this case 2.00M NaCl) • V1 = volume of starting solution required (always unknown) • M2 = molarity of final solution after dilution (in this case 0.100M NaCl) • V2 = volume of final solution, after dilution (in this case 250ml) • M1 V1 =M2 V2 • V1 = M2 V2 / M1 • V1 = (0.100M) x (250 ml) / (2.00M) = 12.5ml

Osmotic Pressure Osmosis: Movement of water through a semipermeable membrane, from more dilute solution towards more concentrated solution Osmotic pressure: amount of pressure required to stop flow of water due to osmosis Isotonic solutions: solutions with identical osmotic pressure; no urge for water to flow

Example: During osmosis, water flows across the semi-permeable membrane from the 4% starch solution into the 10% solution. 4% starch 10% starch H2O

Eventually, the flow of water across the semi-permeable membrane becomes equal in both directions. 7% starch 7% starch H2O

Hypotonic solution: the more dilute of 2 solutions separated by a semipermeable membrane; water leaves this solution and flows across membrane to the more concentrated solution Hypertonic solutions: the more concentrated of 2 solutions separated by a semipermeable membrane; water enters this solution, moving across the membrane from the more dilute solution Crenate Burst No Change (hypertonic) (hypotonic) (isotonic)

Properties of Solutions