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Bonding

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Physical Science Chapter 7: Atoms and Bonding ... Bonding – PowerPoint PPT presentation

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Title: Bonding


1
Bonding
2
The Properties of a Compound are Different from
the Properties of the Elements that make up that
Compound
Calcium Chloride
Calcium
Chlorine
Copper Chloride
Copper
Chlorine
3
Chemical Formula Used to represent the kinds
and numbers of atoms in a chemical compound.
HC2H3O2
Subscript
Be(ClO2)2
Subscript multiplies to all subscripts in
parentheses!
  • NaHCO3 MgCl2
  • Al(OH)3 Ca(NO3)2

4
What must happen for elements to react with each
other?
  • Atoms of the elements must collide.
  • The valence electrons are what actually collide
    in when elements form compounds.
  • This is because the valence electrons are the
    outermost layer.

5
Valence Electrons
  • The electrons in the outermost energy level of an
    atom
  • Responsible for an atoms chemical properties

6
LEWIS DOT DIAGRAMS
  • A diagram where dots are placed around the
    chemical symbol of an element to illustrate the
    valence electrons

7
Octet Rule
  • Octet 8
  • States that atoms tend to gain, lose or share
    electrons in order to acquire a full set of
    valence electrons.
  • For most elements this is 8 valence electrons
  • Hydrogen Helium only require 2 valence
    electrons
  • The elements are all trying to be like the Group
    18 elements, the noble gases b/c they have 8
    valence electrons
  • Atoms form compounds to become stable!

8
How do atoms obtain a noble gas configuration?
  • By sharing or transferring electrons with other
    atoms
  • Example Show how Na Cl can become stable.
  • The bond between Na Cl is due to

9
ANIONS Have gained electrons and have a
negative charge (nonmetals)
If atoms transfer electrons to form a bond they
become IONS
ION AN ATOM THAT HAS AQUIRED A CHARGE BY
GAINING OR LOSING ELECTRONS
CAIONS Have lost electrons and have a positive
charge (metals)
10
Ionic Compound Compound formed from ionic bonds
  • Ionic Bond The strong attractive force between
    ions of opposite charge. Occurs when one atom
    transfers electrons to another atom to become
    stable

11
EMPIRICAL FORMULA
  • Chemical formula for an ionic compound
  • Lowest whole number ratio of ions in an ionic
    compound

12
Types of elements in an ionic compound
  • An ionic bond is formed between a ______________
    and a __________ because
  • Ionic bonds are formed between ions of opposite
    charge
  • Therefore, ionic bonds form between ____________
    and _____________ because metals form cations and
    nonmetals form anions.

nonmetal
metal
nonmetal
metal
13
How do Ionic Compounds Form?
  • Electrons are _______________________ in an ionic
    bond because one atom is trying to lose
    electrons to become stable and the other atom is
    trying to gain electrons to become stable

transferred
14
EMPIRICAL FORMULA
  • Al2O3

Subscript written to the lower right of a
chemical symbol that shows the number of atoms of
that element present in the compound
  • 3 WAYS TO DETERMINE AN EMPIRICAL FORMULA
  • Use Lewis Dot Diagrams
  • Use charges
  • Use the Crisscross Method

15
DETERMINING THE EMPIRICAL FORMULA BY USING LEWIS
DOT DIAGRAMS TO ILLUSTRATE THE IONIC BOND
1
  • Draw the Lewis Dot Diagram for each element
  • Use arrows to show the transfer of electrons
    between atoms
  • Determine the number of each element necessary to
    make each atom

16
PROPERTIES OF IONIC COMPOUNDS
  • Made of ions
  • Typically a metal and nonmetal(s)
  • Crystalline Solids
  • Hard yet Brittle
  • Strong Interparticle Forces
  • High Melting and Boiling Points
  • Will conduct electricity when molten or dissolved
    in water

17
INTERPARTICLE FORCES Forces of attractions
between neighboring particles (atoms, ions or
molecules)
Strong
  • Ionic compounds have __________________
    interparticle forces due to the strong
    electrostatic attraction between the cation(s)
    and anion(s)
  • Because of these ________________ interparticle
    forces,
  • ionic compounds have _____________ melting
    points.

Strong
high
18
CRYSTAL A regular, repeating arrangement of
ions in an ionic compound
The arrangement of ions in an ionic compound
determines the crystal structure (shape) of the
crystal itself.
19
CRYSTAL
  • CaCl2

20
ELECTROLYTE A compound that conducts an
electric current when it is in an aqueous
solution or in a molten state
  • http//www.youtube.com/watch?vEBfGcTAJF4o

21
IONIC COMPOUNDS
  • Ions of opposite charge strongly ___________ each
    other. Ions of like charge strongly
    ______________ each other.
  • As a result of this, how are ions arranged in an
    ionic compound?

attract
repel
Positive ions tend to be near negative ions and
farther from other positive ions.
22
Metallic Bonding The attraction of free floating
valence electrons for the positively charged
metal ions.Made of just metal atoms
  • Pure metals are not simply 1 atom of the metal.
    They are multiple atoms of that metal bonded by a
    sea of electrons.

23
Metallic Properties Come From their Sea of
Electrons
  • Metallic bonds form from a Sea of Electrons
    The pool of electrons shared by all the atoms in
    a metallic substance

24
Malleability The ability to be hammered into
sheets
  • Metals are malleable because the metal atoms can
    slide through the electron sea to new positions

25
Ductile Able to be pulled into wires
  • Metals are ductile because electrons in the sea
    of electrons move to allow atoms to align like a
    wire

26
Conductivity
  • Electricity is caused by moving electrons
  • Metals conduct because the sea of electrons is
    free to move and, therefore, free to conduct
    electricity

27
Interparticle Forces
  • Metallic bonds have strong interparticle forces.
    For this reason metals
  • Are typically solids
  • Are crystalline
  • Metals are arranged in very compact and orderly
    patterns
  • Have average to high melting

28
ALLOY A mixture composed of 2 or more elements,
at least 1 is a metal
NAME OF ALLOY MAKE UP EXAMPLE
Stainless Steel 73-79 Fe 14-18 Cr 7-9 Ni
Sterling Silver 92.5 Ag 7.5 Cu
18-karat white gold 75 Au 12.5 Ag 12.5 Cu
14 karat gold 58 Au 14-28 Ag 14-28 Cu
29
Covalent Bonding Bonding in which electrons are
shared
  • Electrons spend most of their time between the
    atoms.
  • The attraction between the nucleus and the shared
    electrons holds the atoms together.

30
Molecular Compound
  • Compound formed by covalent bonds (from the
    sharing of electrons)

31
Covalent Bonds
  • Form molecules instead of crystals.
  • Molecule The combination of atoms formed by a
    covalent bond

32
Types of Elements in a Covalent Bond
  • Therefore, covalent compounds are formed between
    2 or more ____________________ because
    _____________ are the type of element that want
    to gain, not lose, electrons.
  • In a covalent bond, the atoms share electrons
    because both atoms want to gain electrons.

nonmetals
nonmetals
33
Ionic Compound (Metal Nonmetal) or Covalent
Compound (All Nonmetals)
Which type of bond would form between the
following elements? MgCl2 NI3 AlN CO2 F2
SnO2
34
How do Covalent Bonds Form?
Two nonmetals share electrons to form a bond
35
Covalent Bonds
  • Structural Formula Shows the arrangement of
    atoms in a molecule or polyatomic ion

Space Filling Model Ball Stick
Model Structural Formula
O
?
H
H
36
LEWIS STRUCTURES
  • Uses dashes and dots to show the bonding
    arrangement of atoms in a covalent compound
  • Drawn to model the bonding in a covalent
    compound.
  • Based on Lewis Dot Diagrams
  • Dashes (?) Each dash represents a bond (or 2
    shared electrons)

LONE PAIR
37
Single Covalent Bond
  • 1 shared pair of electrons between 2 atoms
  • Represented by ?
  • Example

38
Double Covalent Bond
  • 2 shared pairs of electrons between 2 atoms
  • Represented by
  • Example

39
Triple Covalent Bond
  • 3 shared pairs of electrons between 2 atoms
  • Represented by
  • Example
  • Lone Pairs (??) Represents an unshared pair of
    electrons

40
Using Lewis Dot Diagrams to Determine the Lewis
Structure
  • Draw the Lewis Dot Diagrams for each atom in the
    Molecular Formula
  • Determine how the atoms will SHARE electrons so
    that all atoms are

41
(N-A)/2 of Bonds in Molecule
  • N of electrons needed to make an each element
    in the compound stable
  • N 8 electrons for all elements except H and He
    which need 2 electrons
  • A of valence electrons each element in the
    compound has
  • There are 2 electrons per bond so we divide the
    of electrons they need to share by 2 to determine
    the number of bonds

42
Some General Guidelines
  • Carbon is typically in the center of the molecule
  • If possible, keep the molecule symmetrical
  • Hydrogen the halogens can only accept one
    electron and, therefore, tend to be on the
    perimeter of the molecule
  • Sometimes, the formula will help you figure out
    the structure
  • Check your work Do all atoms have 8 electrons?
    Does H have only 2 electrons?

43
(N-A)/2 of Bonds in Molecule
  • NH3 Cl2 CH4

44
(N-A)/2 of Bonds in Molecule
  • H2CO C2H2 NH4

45
Resonance Structures Two or more equally valid
structures of a molecule or polyatomic ion
46
Exceptions to the Octet Rule
  • 1) Atoms with less than an octet
  • Boron may not acquire a full octet, it may only
    obtain 6 electrons--it has only 3 valence
    electrons to start
  • Atoms with more than an octet
  • Especially phosphorus sulfur
  • Molecules with Odd Numbers of Electrons
  • Any molecule that has an odd number of available
    electrons, especially compounds of Nitrogen

47
Coordinate Covalent Bond
  • A covalent bond in which one atom contributes
    both bonding electrons

?
?
O
C
?
C
O
?
?
?
?
?
?
?
?
?
?
?
48
Properties of Covalent Compounds
  • Made of molecules
  • All nonmetals
  • Often liquids or gasses
  • Brittle if solid
  • Weak Interparticle Forces
  • Low Melting and Boiling Points
  • Do not conduct electricity when molten or
    dissolved in water

49
More Properties
  • Covalent compounds have ______________
    interparticle forces
  • Because of these _______________ interparticle
    forces, covalent compounds have low melting and
    boiling points
  • Bond Dissociation Energy The energy needed to
    break the bond between two covalently bonded
    atoms
  • A high bond dissociation energy corresponds to a
    strong covalent bond

weak
weak
50
Ionic Covalent Metallic
Type of Elements
State
Electrons are
Hard or brittle?
Melting Points
Made of
51
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52
MOLECULAR GEOMETRY
  • VSEPR THEORY
  • Valence Shell Electron Pair Repulsion Theory
  • In small molecules, the pairs of valence
    electrons are arranged as far apart from each
    other as possible

YES!!!
NO!!!
53
Ball-and-Stick Models
  • Drawings that represent molecular compounds. The
    balls are used to represent atoms and the sticks
    are used to represent bonds.

54
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55
VSEPR Theory Electrons repel (bonds lone
pairs move as far apart as possible)
56
Bond Angles
  • The geometric angle between 2 bonds

57
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58
Other Shapes
Octahedral SF6
T-Shaped ICl3
Square Planar XeF4
Trigonal Bypyramidal PF5
59
EXAMPLES
  • CO2 PF3 CBr4

60
Bond Length
  • Different pairs of atoms form bonds with
    different lengths
  • Not represented in a ball-and-stick model
  • As you move down a group on the periodic table,
    the atoms form longer bonds because the atoms
    become larger
  • Multiple bonds are shorter than single bonds
  • The more electrons there are, the more attraction
    there is for the opposite nuclei
  • Bonds are electrical glue

61
Electronegativity The ability of an atom to
attract electrons when the atom is in a compound
  • Shows how much an atom will attract valence
    electrons
  • The higher the electronegativity the more an atom
    attracts the electrons towards it

62
?EN
  • The difference between two atoms
    electronegativities determines the type of bond
    formed between those two atoms
  • ?EN EN1-EN2
  • ? is the Greek Letter delta and means change
  • ?EN is always positive (always subtract the
    smaller number from the larger number)
  • Example Calculate the ?EN between Cesium and
    Fluorine

63
You can think of bonding as a tug-of-war for
electrons between atoms
  • The electronegativity of the atom tells you how
    hard that atom is pulling for the electrons

64
Ionic Bond
  • When one atom wants the electrons so much more
    than the other atom that it pulls the electron
    off the other atom (a tug-of-war where one side
    wins)
  • ?EN gt 2.0 (greater than 2.0)

65
Nonpolar Covalent Bond
  • Like an even tug-of-warboth atoms want the
    electrons equally so the electrons stay between
    them
  • ?EN lt 0.4 (less than 0.4)

66
Polar Covalent
  • One atom wants the electrons more than the other
    but not enough to pull it all the way towards
    itselflike an uneven tug-of-war
  • ?EN is between 0.4 2.0

67
Electronegativity Difference
?EN EN1 EN2
Nonpolar
Polar
Ionic
0.0
0.4
2.0
68
Polar Covalent Bonds
  • Polar bonds have partially charged atoms due to
    the unequal sharing of electrons
  • Dipole A partial charge on an atom.
  • If the ?EN on a bond is between 0.4 and 2.0 then
    that bond has a dipole (partial charge)
  • This is because one atom wants the electrons more
    than the other but not enough to cause a complete
    transfer

69
DIPOLE
  • ? Symbol for a dipole or a partial charge
  • Used to label the partial charges on a polar bond
  • Two ways to label the dipoles (partial charges)
    on a polar bond

C-Cl
?
?-
F
H
F
H
or
2.1
4.0
?EN 4.0-2.10.9 (polar)
70
Images of Polar/Nonpolar
Nonpolar Polar Polar
71
To determine the polarity of a molecule
  • Does the molecule have only nonpolar bonds?
  • YES It is nonpolar
  • Is the molecule completely symmetrical in all
    dimensions?
  • YES It is nonpolar
  • If the molecule contains at least 1 polar bond
  • and is not completely symmetrical in all
  • dimensions, then the whole molecule is POLAR

72
Polarity of Carbon Dioxide
  • CO2

73
Polarity of Ammonia
  • NH3

74
  • H2O

75
  • CH4

76
The Periodicity of Electronegativity
77
Electronegativity Differences Bonding
  • The greater the difference between the
    electronegativities of the bonding atoms, the
    more unequally those atoms share electrons
  • The symbol for electronegativity difference ?EN

78
Ionic Bonds
  • ?EN is gt 2.0
  • This is because one atom wants the electrons much
    more than the other
  • Because of the high ?EN you can assume that the
    electron on the less electronegative atom is
    transferred to the other atom

79
Nonpolar Covalent Bonds
  • ?EN is lt 0.4
  • This is because both atoms have almost an equal
    attraction for the electrons
  • Because of the low ?EN the atoms are shared
    equally
  • These molecules are gases or low-boiling point
    liquids at room temperature
  • These bonds are also known as Nonpolar Covalent
    Bonds

80
Example
  • Label the dipoles on a C?Cl bond.
  • Could also use vectors to label a polar bond.
  • Example Use a vector to label the dipoles on a
    C-Cl bond.

81
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82
To determine the polarity of a molecule
  • Draw the Lewis Structure of the Molecule with the
    correct geometry
  • Use electronegativity values to determine if any
    of the individual bonds are polar. If so, label
    the dipoles.
  • Using vector addition, check to make sure the
    dipoles do not cancel out.
  • If at least 1 vector/dipole does not cancel out,
    the molecule is polar.
  • If all the vectors/dipoles do cancel out, the
    molecule is nonpolar
  • Vectors will only ALL cancel out if the molecule
    is linear or tetrahedral and completely
    symmetrical!

83
VECTOR ADDITION
  • Involves vector addition.



0


84
Polarity of Ammonia
  • NH3

85
  • H2O

86
IodineI2
87
Methanol CH3OH
88
Dimethyl Ether (CH3)2O
89
EXAMPLES
  • CO2 CH4 CH2O

90
Properties of Polar Covalent Bonds
  • Higher Boiling Points than Nonpolar Covalent
    Bonds
  • Molecules can stick together and form puddles
  • Hydrophilic ionic polar (mix easily with
    water)
  • Like dissolves like

91
Large Molecules
  • In a large molecule the polarity oftentimes
  • helps determine the molecules shape.

92
ATTRACTIONS BETWEEN MOLECULES
  • Responsible for determining whether a
  • molecular compound is a gas, liquid or
  • solid at a given temperature.

93
Van der Waals Forces
  • Consist of Dipole Interactions Dispersion
  • Forces
  • Dispersion Forces Caused by the motion of
    electrons
  • Weakest of all molecular interactions

Dipole Interactions Occur when polar molecules
are attracted to one another Similar to but much
weaker than ionic bonds
94
Hydrogen Bonds
  • The attraction to a hydrogen atom already
  • bonded to a strongly electronegative atom
  • Strongest of intermolecular forces.
  • Extremely important in determining the properties
    of water and biological molecules
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