Chapter 51 Example NO 2 ( ) nitrogen ( ) oxide 2 O’snitrogen dioxide 1 NMononitrogen dioxide often...

Chapter 5 1

Example

NO2 ( ) nitrogen ( ) oxide

2 O’s nitrogen dioxide

1 N Mononitrogen dioxide

often omit “mono”

Nitrogen dioxide

Chapter 5 2

Name the following:

CCl4

N2O3

SiS2

Chapter 5 3

Name the following:

CCl4 carbon tetrachloride

N2O3dinitrogen trioxide

SiS2 silicon disulfide

Chapter 5 4

Write the formula for

dihydrogen monoxide

Silicon tetrafluoride

dinitrogentetroxide

Chapter 5 5

Write the formula for

dihydrogen monoxide H2O

Silicon tetrafluoride SiF4

dinitrogen tetroxide N2O4

Chapter 5 6

Lewis Dot Structures

Helpful in determining 3-D Shape of molecule

Can use 3-D shape to predict properties of molecules

Chapter 5 7

Rules for Lewis structures for molecules

1.Put in the atoms and arrange them to show which atoms are connected to which other atoms.

H always on outside

2.Count the total number of outer shell electrons available to form bonds.

Each atom contributes its group # of e-

Chapter 5 8

3. Draw bonds between atoms. Add in the remaining available electrons in pairs, starting with outside atoms to make octets

4. Make double or triple bonds if necessary to form complete octets around each atom. (Move e- pairs)

Exceptions to full octetH needs only 2 e-

B needs only 6 e-

Period 3 or higher can have > 8

Chapter 5 9

Double check to make sure all atoms have full octets!!!

Chapter 5 10

Draw Lewis structures for:

H2

HCl

PH3

CO2

Chapter 5 11

Resonance

Some compounds can have “equivalent” resonance structures (SO2)

Only difference is “placement” of double bond

Two structures are known as resonance forms

Chapter 5 12

In actual fact, neither double bond structure exists

True situation is resonance hybrid

(midway between two resonance structures)

Chapter 5 13

Types of Covalent Bonds

Bond Type Pairs of e- Total electrons

Single 1 2

Double 2 4

Triple 3 6

Unshared pairs of electrons are known as non-bonding pairs or lone pairs

Chapter 5 14

Bond Energy

Bond energy is amount of energy required to break a bond

Bond energies measured in J or kJ

Stronger bonds have higher bond energy

Triple > Double > Single

Chapter 5 15

Bond Length

Bond length is distance between two nuclei

Shorter in multiple bonds

Length of Bond:

Triple < Double < Single

Chapter 5 16

Valence Shell Electron Pair Repulsion (VSEPR)

Electron “pair” groups in the outer shell of atoms arrange themselves as far away from each other as possible.

Electron group occupies one region of space:

bonding pair of electrons

nonbonding pair of electrons (lone pair)

double or triple bond

Chapter 5 17

Molecular Geometry

Arrangement of atoms around a central atom

Look at one center at a time

Chapter 5 18

Central atom with:

Two bonding regions

(attached to two atoms)

No lone (nonbonding) pairs

Arrangement is linear

Bond angles are 180o

Chapter 5 19

Chapter 5 20

Central atom with:

Three bonding regions

(attached to three atoms)

No lone (nonbonding) pairs

Arrangement is planar

(molecule is flat)

Bond angles are 120o

Chapter 5 21

Chapter 5 22

Central atom with:

Four bonding regions

(attached to four atoms)

No lone (nonbonding) pairs

Arrangement is tetrahedral

Bond angles are 109.5o

Chapter 5 23

Chapter 5 24

Representing 3-D Structures

Solid line: bonds in plane of paper

Dotted wedges: bonds that project behind (or beneath) the plane

Solid wedges: bonds that project in front of (or above) the plane

Chapter 5 25

Chapter 5 26

Geometry of Atoms with Lone Pairs

Two bonding regions

(attached to two atoms)

One lone (nonbonding) pair

Arrangement is angular (bent)

(molecule is flat)

Bond angles are 120o

Chapter 5 27

Chapter 5 28

Geometry of Atoms with Lone Pairs

Three bonding regions

(attached to three atoms)

One lone (nonbonding) pair

Arrangement is trigonal pyramidal

Bond angles are 107o

Chapter 5 29

Chapter 5 30

Geometry of Atoms with Lone Pairs

Two bonding regions

(attached to two atoms)

Two lone (nonbonding) pairs

Arrangement is angular (bent)

Bond angles are 104.5o

Chapter 5 31

Why are bond angles smaller than 109.5o?

Bonding electrons have an atom on both sides of the bond

Lone pairs tend to spread and force the bonding pairs closer together

Chapter 5 32

Chapter 5 33

Fig. 4.8

Chapter 5 34

Fig. 4.9

Chapter 5 35

Summary of Effects of Lone Pairs on Bond Angles

OHH

104.5O107O

NHH

HC

H

HHH109.5O

Chapter 5 36

Summary of Molecular Geometry

# Electron Lone Bond Angle Shape regions pairs

2 0 180o Linear

3 0 120o Planar 2 1 Angular (bent)

4 0 109.5o Tetrahedral 3 1 Trigonal pyramidal 2 2 Angular (bent)

Chapter 5 37

Review: Electronegativity

Measure of the relative pull of an atom on a shared pair of electrons

Arbitrary scale ranging from 0 to 4

Most electronegative element is fluorine

F has E = 4

Chapter 5 38

Electronegativity Values

Chapter 5 39

Polarity of bondsCovalent Bonds between atoms with similar electronegativity values are nonpolar

Δ E < 0.5

Covalent Bonds between atoms with different electronegativity values are polar covalent

0.5 < Δ E < 1.9

Bonds between atoms with very different electronegativity values are ionic

Δ E > 1.9

Chapter 5 40

Polar Bond has positive and negative ends to the bond (uneven distribution of charge)

Polar molecule has positive and negative ends to the molecule (even distribution of charge)

Chapter 5 41

Polar Bond has positive and negative ends to the bond

Polar molecule has positive and negative ends to the molecule

Molecule acts like a dipole

Chapter 5 42

Polar Covalent Bonds---Unequal Sharing of Electrons

Chapter 5 43

Dipoles can align in an electrical field

Nonpolar molecules do not have +/- ends and do not align in electrical field

Chapter 5 44

Nonpolar molecule

All of the bonds are C—H bonds.

C end is slightly negative compared to H end for each bond

Overall, molecule is nonpolar because it does not have positive and negative ends---Polarities cancel out

Chapter 5 45

Polar Molecule

Each O—H bond is polar

O end is more negative than H end

Negative end to molecule

Polarities do not cancel each other----instead are additive

Chapter 5 46

• Intramolecular Forces– Forces within molecules

Covalent bonds

• Intermolecular Forces– Forces between molecules

Hydrogen bonds Dipole-dipole interactions Dispersion Forces

Chapter 5 47

Intermolecular Forces

• Hold matter together

• Boiling point and melting point a good measure of how strong intermolecular forces are

Chapter 5 48

More energy is required to separate molecules held together by strong intermolecular forces than weak intermolecular forces.

Materials with strong intermolecular forces have higher boiling points and melting points

Chapter 5 49

Ionic Forces

• Interaction between + and – charges on ions

• Strongest intermolecular forces– Found in salts– NaCl melts at 801oC

Chapter 5 50

Hydrogen Bonds• H that is covalently attached to O, N or F is

attracted to a different O, N or F

• This attraction is a “hydrogen bond”

• Much weaker than ionic forces or covalent bonds (intramolecular bond) between atoms

• Important in biological systems

• Water melts at 0oC

Chapter 5 51

Hydrogen Bond

Chapter 5 52

Dipole Forces

• Result from attraction between partially positive and partially negative ends (poles) of molecules

• Works only for polar molecules

• HCl melts at -112oC

Chapter 5 53

Dipole Forces (a=solid, b=liquid)

Chapter 5 54

Dispersion Forces (London)

• Present in all molecules

• Weak temporary forces that result from movement of electrons within molecules and around atoms– Important in nonpolar materials– Each individual London force is very weak,

but together they add up, especially for large molecules

Chapter 5 55

Intermolecular Forces

Strongest

Ionic forces (much stronger)Hydrogen bondingDipole ForcesDispersion Forces

Weakest

Chapter 5 56

Properties affected by Intermolecular Forces

Melting points

NaCl > H2O > HCl > CH4

mp 801 0 -112 -182.5oC

Ionic H-bond Dipole London

Chapter 5 57

States of Matter

Solid

Liquid

Gas

Chapter 5 58

States of Matter

Solid Liquid Gas

Definite shape

Yes No No

Definite volume

Yes Yes No

Is fluid (Pours or Flows)

No Yes Yes

Chapter 5 59

Solid Liquid Gas

Interactions between Particles

Strong Moderate None

Particles touching

Yes Yes (some holes)

No

Space between particles

No Some holes

LOTS of space

Chapter 5 60

Changes of State

Melting:

Change from the solid to the liquid state

Freezing:

Change from the liquid to the solid state

(solidification or crystallization)

Chapter 5 61

Changes of State

Vaporization:

Change from the liquid to the gaseous state (Evaporation or Boiling)

Condensation:

Change from the gaseous to the liquid state

Chapter 5 62

Changes of State

Sublimation:

Change from the solid to the gaseous state directly (skips liquid state)

Deposition:

Change from the gaseous to the solid state directly (skips liquid state)

Chapter 5 63

Melting point:

Temperature at which substance goesfrom solid to liquid state

Boiling point:

Temperature at which substance goes from liquid to gaseous state

Chapter 5 64

Summary of State Changes

Chapter 5 65

Energy is needed to overcome the forces between molecules

Need to add energy for substance to melt or vaporize (or sublime)

Need to remove energy for substance to condense or freeze (or deposit)

Heat of Vaporization is amount of energy needed to change given amount of liquid into gas at its boiling point

Chapter 5 66

Gases

Lots of space between molecules

Gas molecules can be pushed closer together because there is plenty of space between them

Gases are compressible

Chapter 5 67

Molecules move in straight line until they hit the sides of their container and move in a different direction

When molecules hit container, they exert a force

Pressure: Force per unit area

Chapter 5 68

Pressure units

Atmosphere:

1 atm is pressure at sea level

mm Hg:

760 mm Hg is pressure at sea level

1 atm = 760 mm Hg

Chapter 5 69

Boyle’s Law

Pressure (P) and Volume (V) of a gas are inversely proportional

P α 1/V or PV = constant

Raise Pressure → Lower Volume

Lower Pressure → Increase Volume

Chapter 5 70

Chapter 5 71

Chapter 5 72

Charles’s Law

Temperature (T) and Volume (V) of a gas are directly proportional

P α T or P/T = constant

Raise Temperature → Raise Volume

Lower Temperature → Lower Volume

Chapter 5 73

Chapter 5 74

• Solution is homogeneous mixture (mixed uniformly)

Chapter 5 75

Properties of Liquids

Molecules are close together, so liquids are only slightly compressible

Each liquid has a unique vapor pressure

Vapor pressure is the pressure of gas molecules that have escaped the liquid state at a given temperature

(closed container)

Chapter 5 76

Boiling Point

Boiling Point:

Temperature at which vapor pressureis equal to atmospheric pressure

Normal Boiling Point:

Boiling point at 1 atm pressure

Chapter 5 77

Water: Unique Properties

• Water is liquid at room temperature– Hydrogen bonds between water molecules

give water a higher melting point

• Density of ice is less than density of water

• Water has high heat capacity.– Can absorb lots of energy with very little

change in temperatue

Chapter 5 78

Hydrogen Bond

Chapter 5 79

Water: Unique Properties

• Water has high heat of vaporization

• Water has high surface tensionSurface tension: Molecules at surface are only attracted on one side and form a “skin”

• Water is an excellent solvent

Chapter 5 80

Solutions

Solvent: Substance present in greater amount

Solute:Substance present in smaller amount

Solubility:Amount of solute that will dissolve in a given amount of solvent at a given temperature

Chapter 5 81

Saturated solution:

Contains the maximum amount ofsolute it can dissolve

Unsaturated solution:

Contains less than the maximum amount of solute possible (can dissolve more)

Chapter 5 82

Insoluble:Solute will not dissolve in the solvent

Miscible:Solute and solvent will dissolve in all proportions

Chapter 5 83

Solubility

Like dissolves like.

Polar substances dissolve in polar substancesSalt and water, sugar and water

Nonpolar substances dissolve in nonpolar substances

Grease and CCl4

Unlike substances do not dissolve each other

Oil and vinegar

Chapter 5 84

Ionic Compounds in SolutionIons dissolve in water---Charges on ions attracted to partial charges on polar water molecules

Chapter 5 85

Compounds in Solution

Electrolyte:*Compound that conducts electricity when it is melted or dissolved in water *Ions carry charges and conduct electrons*Electrolytes are ionic compounds

Non-electrolyte:*Compound that does not conduct

electricity when it is melted or dissolved in water

*Nonelectrolytes are not ionic compounds

Chapter 5 86

Strong electrolyte:

*Completely separates into ions in solution

*Conducts electricity well

Weak electrolyte:

*Partly separates into ions in solution

*Conducts electricity poorly