1. Liquids
Chapter 10

2. Review: Gases Indefinite shape Indefinite volume
Take the shape and volume of container
Particles are far apart
Particles move fast
Low Density
Easy to expand and compress

3. Review: Solids Definite shape Definite volume
Particles close together, fixed
Particles move very slowly
High density
Hard to expand/compress

4. Liquids: in between Closer to properties of solids Slow diffusion
High attraction between particles
Medium amount of energy

5. Forces of Attraction
Intramolecular forces: Hold atoms together within a molecule
covalent and ionic bonds
Intermolecular forces: Hold molecules to each other
3 types

6. Dipole-Dipole Attraction
Dipole: molecule with a separation of charge (polar covalent)
Due to differences in electronegativity
~1% as strong as a covalent bond

7. Hydrogen Bond
Very strong dipole-dipole attraction (10% of a covalent bond’s strength)
Occurs when H is bonded to O, N, F in a very polar bond
O H
Gives water its unusual properties

8. H-Bonding Affects Boiling Points
Strong attraction requires much energy to overcome, so water is a liquid at normal temperatures

9. London Dispersion Forces
Occur in all substances-polar and nonpolar
Due to formation of instantaneous dipoles as electrons moving around nucleus concentrate on 1 side of molecule or atom

10. This induces a dipole in neighboring atoms or molecules
These are the weakest intermolecular forces
These are the only forces of attraction in nonpolar substances

11. Importance of Water Covers 70% earth’s surface
Necessary for reactions in living cells
Moderates earth’s temperature
Coolant for engines & nuclear power plants
Transportation
Growth medium for many organisms

12. Properties of Water Colorless Tasteless
At 1 atm, water freezes at 0°C and vaporizes completely at 100°C
 Liquid phase occurs from 0-100°C

13. Special Properties of Water
Surface Tension
Liquids tend to form a “skin” making the surface less penetrable by solids

14. Unequal attraction at surface, mainly down
Equal attraction in all directions

15. Surface Tension
Detergents can interfere with the attractions and will cause the paperclip to fall

16. Adhesion
Attraction of the surface of a liquid to the surface of a solid
Depends on the material
Water is attracted to glass
Mercury is not
No adhesion

17. Cohesion Molecular attractions within a material
(water molecules to water molecules, for example)
Here, cohesion
causes water to
form beads; ad-
hesion causes it
to stick to the web

18. Capillary Action
A liquid rises in a narrow tube when it breaks the surface tension
Movement of water through paper

19. Ice Floats!
Molecules in a liquid have more movement than a solid and more energy (particles move apart
Generally, solids are more dense than their ir liquids
Liquid water

20. Ice
When water becomes fixed points in a solid, hydrogen bonds hold molecules in place
Gives ice an open hexagonal structure
Greater volume means lower density than a liquid

21. Higher K.E. causes distance between molecules to be more
Max. density at 4 C
Lower K.E. causes distance between molecules to be less

22. Phase Changes of Water
At 1 atm, water freezes at 0°C and vaporizes completely at 100°C
 Liquid phase occurs from 0-100°C
Changes from one phase to another will either require energy or release energy
Solid Liquid
Liquid Gas
Solid Gas
Melting/Freezing
Vaporization/Condensation
Sublimation/Deposition

23. From Solid to Liquid As energy is added, K.E. increases
Solid warms up
At 0°C, solid begins to melt and temperature remains at 0 until all solid is turned to liquid
When all is liquid, temperature begins to rise

24. From Liquid to Gas
As heat is added, K.E. increases (increase in temperature)
At 100C, bubbles form in liquid
Temperature remains the same until all liquid is converted to a gas.
Once all is a gas, added energy causes temperature to increase

25. Ice melting/water vaporizing
When a substance is in phase, increasing the energy increases the temperature
When a substance is changing phase, increasing the energy does not increase the temperature but is used to break forces of attraction between molecules

26. Phase diagram
Temperature vs. Energy

27. Heating a Solid

28. Melting a Solid

29. Heating a Liquid

30. Vaporizing a Liquid

31. Heating a Gas

32. Calculating Energies Energy is measured in calories or Joules
1.00 cal = J
The amount of energy needed to change states depends on:
Type of matter
Quantity of matter

33. Type of matter
Molar heat of fusion (Hfusion)= energy needed to melt 1 mole of a substance
Molar heat of vaporization (Hvap)= energy needed to vaporize 1 mole of a substance

34. For Water (Hfusion) = 80.0 cal/g = .334 kJ/g
(H vap) = 540. cal/g = 2.26 kJ/g

35. Finding Energy in a Phase Change
Change from a solid liquid
q = mHfusion
Change from a liquid gas
q = mHvap
q = energy (cal or J)
m = mass (g)
Hfusion =heat of fusion (cal/g)
q = energy (cal or J)
m = mass (g)
Hvap =heat of vaporization

36. Example How much heat in calories is needed to melt 15.0 g of water?
q = mHfusion
15.0 g water x cal = x 103 cal
1 g water

37. Energy and Being In Phase
When all of a substance is in one phase, (e.g. all liquid), the amount of energy required to cause a temperature change depends on:
type of substance
amount of substance
range of temperature change

38. Type of Matter
Specific Heat (c): Energy required to change the temperature of 1 gram of a substance by 1 Celsius degree
cg = specific heat of a gas
cl = specific heat of a liquid
cs = specific heat of a solid

39. For Water cg = .480 cal/gC or 2.01 J/gC
cl = 1.00 cal/gC or J/gC
cs = .500 cal/gC or J/gC

40. Finding Energy When In Phase
q = mcT
T = Tfinal – Tinitial
q = energy (cal or J)
m = mass (g)
c = specific heat (cal/gC)
T =change in temperature (C)

41. Example
How much energy is required to heat 50.0 g of water from 20.0 C to 85.0 C?
q = mcl T
T = 85.0 – 20.0 = 65.0 C
q = (50.0g)(1.00 cal/gC)(65.0 C)
q = 3,250 cal

42. Phase changes

43. In Phase

44. Phase diagram
Temperature vs. Energy

45. Phase Change Problems Draw graph. Mark start and stop points.
Every corner means a new equation is needed.
Flat sections will use q = mH ( no T means no slope).
Find each energy (q1, q2, q3..).
Add all energies to get the total energy.

46. Phase Changes
Vaporization (evaporation): molecules of a liquid escape the liquid’s surface
Requires energy to overcome intermolecular forces
Maxwell Boltzman distribution
Molecules with enough energy to evaporate

47. To evaporate, a particle must:
Be at the surface
Have sufficient energy
Be moving in the right direction
I’m free!!
Moving in the wrong direction
Not enough energy
Not at surface

48. Evaporation produces Vapor Pressure
A closed container with a vacuum has a liquid added to it.
Molecules begin to evaporate
Some particles are recaptured by the liquid
Eventually rate of particles leaving = rate of being recaptured

49. Equilibrium Vapor Pressure
When rate of evaporation = rate of condensation the pressure becomes constant (Equilibrium vapor pressure)

50. Vapor pressure and temperature
As temperature increases, more particles evaporate

51. Vapor Pressure
The vapor pressure of substances varies greatly, depending on the strength of the forces of attraction between particles.

52. Volatile liquids evaporate easily
Small particle size
Only London dispersion forces of attraction

53. Boiling
Occurs when the equilibrium vapor pressure reaches atmospheric pressure
Only then can a bubble maintain itself anywhere in the liquid
Air Pressure
Particle of gas exerts pressure on surrounding molecules, pushing them out of the way, and therefore up against air pressure

54. This is the difference between evaporation and boiling

55. As atmospheric pressure changes, so does the equilibrium vapor pressure necessary for boiling to occur
Therefore, the boiling point depends on the pressure

56. Vapor Pressure vs. Temperature can give us the boiling point of a substance at any pressure
The b.p. at 1 atm is called the normal boiling point.

57. P vs. T Phase Diagram
We can expand our graph to see the effect of pressure on melting/freezing and sublimation/deposition
For a “normal” substance:
Increasing pressure raises the melting point (AD)

58. Important Points on Diagram
A: Triple point: temperature & pressure at which solid, liquid and gas coexist at equilibrium
B: Critical Point: indicates critical temp and pressure
Critical Temp: temp above which substance cannot exist in a liquid state
Critical Pressure: lowest pressure required for substance to exist as a liquid at the critical temperature

59. Phase Diagram for Water
Line AB slants backwards.
Increasing the pressure lowers the melting point.

60. 1 atm
100°C
0°C