1. States of Matter Newport High School�Academic Chemistry
2. Lesson 1 Kinetic Molecular Theory Essential Questions:
How does the kinetic-molecular theory describe the properties of gases that include: expansion, fluidity, low density, compressibility, diffusion, and effusion?
Vocabulary: kinetic-molecular theory, ideal gas, elastic collision, diffusion, effusion, real gas
3. Lesson 1 The Kinetic Molecular Theory Kinetic-molecular theory is based on the idea that particles of matter are always in motion.
Can be applied to solids, liquids, and gases.
4. Assumptions of Gases Ideal gas one that behaves in a way to fit all 5 assumptions of the kinetic-molecular theory of gases.
5 Assumptions
Gases consist of large numbers of tiny particles that are far apart.
Collisions between particles are elastic.
Gas particles are in continuous, rapid, random motion.
There are no forces of attraction between gas particles.
The temperature of a gas depends on the average kinetic energy of the particles of the gas.
5. Expansion Gases do not have a definite shape or volume.
Completely fill any container they occupy.
6. Fluidity Gas particles glide past each other because attractive forces are insignificant.
They are considered fluid, because they flow.
7. Low density Density is about 1/1000 the same substance in the liquid or solid state.
Reason is that gas particles are very far apart.
8. Compressibility Gas particles become more crowded when compressed.
Volume can be decreased due to large amount of space between particles.
Examples of compression of gases?
9. Diffusion and Effusion Diffusion spontaneous mixing of the particles of two substances caused by random motion
http://www.indiana.edu/~phys215/lecture/lecnotes/diff.html
Effusion process where gas particles pass through a tiny opening
10. Lesson 2 - Liquids Essential Question:
How does the kinetic-molecular theory of liquids describe the motion of particles and the properties of liquids?
Vocabulary: Fluid, surface tension, capillary action, vaporization, evaporation, freezing
11. Kinetic Molecular Theory & Liquids Liquid = definite volume and takes the shape of its container
Particles are closer together
Attractive forces do exist
More ordered than gases
Particles have lower mobility, but are fluids
12. Properties of Liquids Density
Compressibility
Diffusion
Surface Tension
Capillary action
Evaporation and Boiling
Formation of Solids
13. Density Substances are hundreds of times denser in the liquid state than in the gaseous state
Water is one of the few substances that because less dense when it solidifies.
Most become more dense.
Densities differ so much between liquids that they can form layers.
14. Compressibility They are relatively incompressibile.
Particles are more closely packed.
Volume only decreases by 4% at very high pressures.
15. Diffusion Liquids diffuse in the same way as gases.
Due to random motion of particles.
Is slower than gases since particles are closer together and attractive forces exist.
Increase temperature, increase diffusion
16. Surface Tension Surface tension force that pulls adjacent parts of a liquids surface together, consequently decreasing surface area to the smallest possible size
This is why they form a sphere shape
Higher force of attraction = higher surface tension
17. Capillary action Capillary action attraction of the surface of a liquid to the surface of a solid
Attraction tends to pull the liquid molecules upward along the surface reason for the meniscus
Responsible for the transportation of water in plants.
18. Evaporation & Boiling Vaporization process by which a liquid changes to a gas
Evaporation vaporization without boiling
Boiling energy is added in the form of heat
19. Formation of Solids When a liquid is cooled, the average energy of the particles decreases.
This is called freezing or solidification.
Each substance has its own freezing temperature.
20. Lesson 3 - Solids Essential Question:
How does the kinetic-molecular theory of solids describe the motion of particles in solids and the properties of solids?
Vocabulary: Crystalline solids, crystal, amorphous solids, melting, melting point, supercooled liquids, crystal structure, unit cell
21. Kinetic Theory & Solids Crystalline and amorphous solids
Definite shape and Volume
Shape stays due to arrangement of particles.
Volume only changes slightly with change in temperature.
Definite Melting Point
When particles overcome the forces holding them together.
High Density
Results from the fact that the particles of a solid are more closely packed than liquids or gases
Incompressibility
Low Rate of Diffusion
Millions of times slower than liquids
22. Crystalline Solids Crystal structure 3D arrangement of particles
Unit cell smallest portion of a crystal lattice that shows 3D structure
23. Four Types of Crystals Ionic
Positive and negative ions arranged in a regular pattern
High melting points, hard and brittle, good conductors
Covalent network
Each atom is covalent bonded to its nearest neighbor.
Very hard and brittle, high melting point, nonconductors or semiconductors
Metallic
Metal cations surrounded by a sea of valence electrons
High melting point, good conductors
Covalent molecular crystals
Held together by intermolecular forces
Low melting points, easily vaporized, soft, insulators
24. Amorphous Solids Particles not arranged in an orderly pattern
Most are cooled in ways that do not let them crystallize.
Glass, plastic, rubber, and asphalt are examples.
Have no definite melting point
25. Lesson 4 Phase Changes Essential Questions:
How do phase diagrams show the relationship between the physical states of a substance and its temperature and pressure?
Vocabulary: phase, condensation, equilibrium, vapor pressure, volatile liquid, boiling, boiling point, molar enthalpy of vaporization, freezing point, molar enthalpy of fusion, sublimation, deposition, phase diagram, triple point, critical point, critical temperature, critical pressure
26. Phase Changes
27. Phase Changes Evaporation
molecules at the surface gain enough energy to overcome IMF
Volatility
measure of evaporation rate
depends on temp & IMF
28. Phase Changes
29. Phase Changes Equilibrium
trapped molecules reach a balance between evaporation & condensation
30. Phase Changes Vapor Pressure
pressure of vapor above� a liquid at equilibrium
31. Phase Changes Boiling Point
temp at which v.p. of liquid equals external pressure
32. Phase Changes Melting Point
equal to freezing point
33. Phase Changes Sublimation
solid ? gas
v.p. of solid equals external pressure
34. Heating Curves
35. Heating Curves Temperature Change
change in KE (molecular motion)
depends on heat capacity
36. Heating Curves Phase Change
change in PE (molecular arrangement)
temp remains constant
37. Heating Curves Heat of Vaporization (?Hvap)
energy required to boil 1 gram of a substance at its b.p.
usually larger than ?Hfuswhy?
38. Phase Diagrams Shows the relationship among the solid, liquid, and vapor states.
Each region represents a pure phase
Line between regions is where the two phases exist in equilibrium
Triple point is where all 3 curves meet, the conditions where all 3 phases exist in equilibrium!
39. Phase Diagrams cont. Critical temperature temperature above which a substance cannot be in a liquid state
Critical pressure lowest pressure at which the substance can exist as a liquid at the critical temperature
Critical point critical temperature and pressure
Normal freezing point point at which liquid freezes at sea level
Normal boiling point point at which liquid boils at sea level
40. Lesson 5 - Water Essential Questions:
How are the properties of water determined by its structure?
What happens to the energy of water when it changes state?
Vocabulary: Heat, energy
41. Structure of Water Two hydrogen atoms and one oxygen atom
Molecules in water are linked by hydrogen bonding
Why is water not a gas at room temperature?
Empty space between molecules is why ice has lower density.
42. Physical Properties of Water
43. Works Cited Modern Chemistry Textbook
www.nclark.net
http://mrsj.exofire.net/chem/
http://www.unit5.org/chemistry/
