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CHEMISTRY 2000 Topic #3: Thermochemistry and Electrochemistry – What Makes Reactions Go? Spring 2008 Dr. Susan Lait.

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Presentation on theme: "CHEMISTRY 2000 Topic #3: Thermochemistry and Electrochemistry – What Makes Reactions Go? Spring 2008 Dr. Susan Lait."— Presentation transcript:

1 CHEMISTRY 2000 Topic #3: Thermochemistry and Electrochemistry – What Makes Reactions Go? Spring 2008 Dr. Susan Lait

2 2 Vapour Pressure of Pure Substances When you leave wet dishes on a draining board overnight, they will usually be dry the next morning. The water has evaporated – even though your kitchen was 70-80˚C below the boiling point of the water! How is this possible? At any given temperature, some of the molecules in the liquid will have enough energy to escape the intermolecular forces holding the sample together.

3 3 Vapour Pressure of Pure Substances Heating the liquid increases the rate of vaporization by increasing the proportion of molecules having at least this much energy. Since heating increases the rate of vaporization, this is an __________________ process with a _________ enthalpy. This is consistent with the observation that rapid vaporization cools any remaining liquid. The molecules at the surface with enough energy to evaporate do so, reducing the average kinetic energy of the remaining liquid molecules (thereby reducing the liquid’s temperature). During slow evaporation, heat is steadily resupplied from the environment so we don’t notice this loss. Because there will always be at least a few molecules in a liquid with enough energy to evaporate, there will always be a layer of gas molecules immediately above a liquid. In a sealed container at equilibrium, the pressure exerted by these gas molecules is referred to as the vapour pressure. Vapour pressure is not exclusive to liquids; many solids have a measurable vapour pressure. e.g. dry ice (CO 2(s) ), I 2(s)

4 4 Vapour Pressure of Pure Substances When the vapour pressure of a liquid is equal to the atmospheric pressure, the liquid boils. The pressure exerted by gas molecules is equal to the pressure of the atmosphere pushing down on the liquid’s surface. As such, bubbles of gas can form within the liquid (not just at its surface), they rise, and we observe boiling. The boiling point of a liquid is pressure-dependent. Reducing the pressure will decrease a liquid’s observed boiling point while increasing pressure will increase the observed boiling point. To allow comparisons, we therefore define the temperature at which the vapour pressure of a liquid is equal to ___________________ as a liquid’s normal boiling point. Liquids with a high vapour pressure/low boiling point are referred to as __________________. 1 atm = 1.01325 bar

5 5 Vapour Pressure of Pure Substances Vapour pressure can be read off a vapour pressure curve (like the one on the previous page) or calculated from free energy. e.g. The standard molar free energy change for the evaporation of water is 44.5 kJ/mol.

6 6 Vapour Pressure of Solutions The figure at the right shows vapour pressure curves for pure benzene (in red) and a 2 mol/kg solution (in blue) of a nonvolatile solute in benzene. Adding the solute has lowered the vapour pressure at any given temperature(thereby raising the boiling point) Why does this occur? Consider the difference between a pure liquid and a solution with a nonvolatile solute. e.g. pure water (right) vs. salt water (left).

7 7 Vapour Pressure of Solutions The surface of the pure water consists entirely of water molecules, a fraction of which have enough energy to evaporate. The surface of the salt water consists primarily of water molecules but also some ions from the salt. The same fraction of water molecules has enough energy to evaporate but, since fewer water molecules are on the surface, fewer evaporate. Essentially, the salt ions are “blocking the surface” of the solution. Thus, the salt water has a lower vapour pressure than the pure water. Because of this, the salt water will have to be heated to a higher temperature to raise its vapour pressure to be equal to atmospheric pressure. Thus, the boiling point of salt water is higher than that of pure water.

8 8 Vapour Pressure of Solutions This can be expressed mathematically. Raoult’s law defines the vapour pressure of a solvent (“A”). where P A is the vapour pressure of the solvent (in solution), P A ° is the vapour pressure of the solvent (as a pure liquid) and X A is the mole fraction of the solvent molecules. Note that Raoult’s law only calculates the vapour pressure of the solvent. If a solute is volatile, it will have a vapour pressure too! where [A] is the concentration of the volatile solute “A”, P A is the vapour pressure of the volatile solute and k H is the Henry’s law constant (solute-specific). Unsurprisingly, this is Henry’s law. It is usually presented when discussing solubility of gases.

9 9 Vapour Pressure of Solutions The standard molar free energy change for the dissolution of oxygen in water is 16.35 kJ/mol. Calculate the Henry’s law constant for oxygen in water.

10 10 Equilibrium Constant and Temperature An equilibrium constant (K) is only constant as long as the temperature doesn’t change! Why? The enthalpy and entropy change for a reaction vary slowly with temperature; however, the free energy change is strongly temperature-dependent: At any temperature: So, as T changes,  G changes and therefore K changes.

11 11 Equilibrium Constant and Temperature When comparing a reaction at temperatures T 1 and T 2, we can say that: If we approximate that the values of  H and  S don’t change significantly over the given temperature range, we can combine these equations and simplify to get: or: and

12 12 Equilibrium Constant and Temperature You have probably been taught that K w = 10 -14 under standard conditions (making neutral water have pH 7 at 25 °C). What is K w at 37.00 °C?

13 13 Equilibrium Constant and Temperature What does this tell us about the pH of water at 37.00 °C?

14 14 Equilibrium Constant and Temperature Recall that the boiling point of a liquid is the temperature at which its vapour pressure equals the atmospheric pressure. If the atmospheric pressure in Lethbridge is typically 90 kPa, what is the boiling point of water on a typical day in Lethbridge?

15 15 Equilibrium Constant and Temp. (Solutions) When we looked at Raoult’s law, we noted that if adding a nonvolatile solute to a solvent lowered the vapour pressure, it must therefore elevate the boiling point. Calculate the normal boiling point of a solution prepared by dissolving 0.5 mol NaCl in 1 kg (55.51 mol) of water.

16 16 Equilibrium Constant and Temp. (Solutions) How does adding a nonvolatile solute to a solvent affect its freezing point? (also known as its melting point) Calculate the freezing point of a solution prepared by dissolving 100 g (0.292 mol) sucrose in 500 g (27.8 mol) of water.

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