Chapter 10

1. Chapter 10 States of Matter

2. 10.1 Kinetic Molecular Theory (KMT) “Particles of Matter are always in motion” States of Matter We will discuss the KMT in terms of : 1. Gases 2. Liquids 3. Solids

3. KMT - Gases • Ideal gas- follows all of the tenets of the KMT. • 1. Gases consist of large numbers of atoms/molecules that are in continuous, random motion. • 2. The combined volume of all the atoms/molecules of the gas is negligible relative to the total volume in which the gas is contained.

4. Gases Cont. • 3. Attractive and repulsive forces between gas particles is negligible. • 4. Energy can be transferred between particles during collisions, but the average kinetic energy of the particles does not change with time (assuming temperature is constant) = collisions are elastic • 5. The average kinetic energy of the particles is proportional to the absolute temperature. • K.E. = ½ mv2

5. Properties of Gases • Expansion-gases occupy the volume of the container they are enclosed in. • Fluidity- gas particles move like liquids because there are no attractive or repulsive forces among them • Density- gases have low densities because of the large amounts of space between the particles.

6. Properties of Gases Cont. • Compressibility- Gases can be easily condensed with an increase in pressure due to the large space between the particles. • Diffusion- the random mixing of particles due to their constant motion. • Effusion- gas particles pass through a tiny opening. • Rate is directly proportional to the velocities of the particles. (Smaller particles move faster and vice-versa)

7. Real Gases • Those that do not conform to the 5 parts of the KMT. • When gases are held at high pressure and low temperatures they deviate from their expected behavior. • Noble gases conform the most to the KMT and act like ideal gases. • The more polar the gas molecule the more it deviates from the KMT and acts like a real gas.

8. 10.2 Liquids • Have a definite volume and take the shape of its container • Particles are closer together so their attractive forces are stronger than in gases (think strength of intermolecular forces) • Fluid – the ability to flow and occupy the shape of its container.

9. Liquids Cont. • Density – fairly high considering the closer arrangement of the particles • Incompressibility- because of the close proximity to one another, the particles in a liquid can’t be pushed much closer together. • Diffusion- liquids move easily among other liquids. Attractive forces and temperature of the particles lends to a slower diffusion rate of the liquid particles.

10. Liquids Cont. • Surface Tension- a force that attracts adjacent particles on a liquids’ surface together enough to decrease the surface area. • The higher the intermolecular forces the higher the surface tension. • Water has a fairly high surface tension.

11. Liquids Cont. • Capillary Action – the attraction of the surface of a liquid to the surface of a solid. • Meniscus • Chromatography • Phloem tubes in plants

12. Liquids Cont. • Vaporization – liquid changing to a gas • Evaporation – vaporization at the surface of a liquid • Individual particles gain enough kinetic energy to break the I.F. and escape as a gas. • Freezing – liquid changing to a solid • Due to the increased intermolecular attractions among the particles

13. 10.3 Solids • Highly ordered arrangement with minimal movement among the particles • I.F. exert stronger forces due to this proximity • Types: • Crystalline- geometric, repeating pattern of particles • Amorphous- random arrangement of particles • Glass, obsidian • “without shape”

14. Solids Cont. • Melting- changing a solid to a liquid by applying heat energy • Overcome I.F. and break apart from the crystalline structure • Supercooled liquids (amorphous solids) – retain some liquid properties due to their lack of a uniform, organized pattern • High Density • Low diffusion rate

15. Solids Cont. • Types of Crystals (p. 340) • 1. Ionic - NaCl • 2. Covalent Network – SiO2 • 3. Metallic - Cu • 4. Covalent Molecular – NH3

16. Changes of State • Phase – when a substance has uniform composition and properties • Melting, freezing, vaporization, condensation, sublimation, deposition • Equilibrium – when two phases occur at the same rate. E.g., melting freezing

17. Changes of State Cont. • Equilibrium Vapor Pressure – the pressure exerted by a vapor in equilibrium with its liquid at a given temp. • Proportional to the concentration of molecules in the vapor phase. • Increases with an increase in temperature • Volatile liquids (those that evaporate easily) have higher V.P. because they tend to have weaker I.F. between the molecules. • Vapor Pressure Animation

18. Changes of State Cont. • Boiling – change of a liquid to vapor at the surface and within the liquid. • Boiling point – when the V.P. equals the atmospheric pressure. • Normal B.P. of water = 100oC, (normal atmospheric pressure of 1 atm, 760 torr, 101.3 kPa) • B.P. Animation

19. Vapor Pressures of Various Substances

20. Identity of Substances • A – Diethyl ether • B – Benzene • C - water

21. Phase Diagrams • Phase Diagram Explanation

22. Phase Diagram for Water