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COVALENT BONDING

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Title: COVALENT BONDING


1
COVALENT BONDING
  • Chapter 16

2
AND THE SUBJECTS ARE
  • THE NAME IS BOND, COVALENT BOND
  • SINGLES, DOUBLES TRIPPPLES
  • COORDINATE COVALENT BONDS
  • RESONATE THIS!
  • THERES ALWAYS AN EXCEPTION
  • PRINCESS VSEPR
  • HYBRIDS
  • DISSOCIATIONS AND ATTRACTIONS

3
YOU KNOW THAT YOU MAY BE A COVALENT BOND WHEN
  • ELECTROSTATIC FORCES ARE WEAK
  • r ELECTRONEGATIVITY IS SMALL
  • THERE ARE NO METAL CATIONS
  • IONS DONT GET OR LOSE ELECTRONS

4
SINGLE COVALENT BOND
  • HYDROGEN
  • H H ? HH
  • Hydrogen Hydrogen Hydrogen
  • Atom Atom
    molecule
  • HYDROGEN ATOMS FORM SINGLE BONDS

Shared electron pair
5
SINGLE COVALENT BOND
  • DIATOMIC MOLECULES
  • HYDROGEN NITROGEN OXYGEN FLUORINE
    CHLORINE BROMINE
  • IODINE
  • r ELECTRONEGATIVITY 0
  • SHARED ELECTRONS

6
SINGLE COVALENT BOND
  • FOR CHLORINE,
  • 1s 2s 2p 3s 3p
  • Cl ?? ?? ?? ?? ?? ?? ?? ?? ?_
  • Cl ?? ?? ?? ?? ?? ?? ?? ?? _?

7
SINGLE COVALENT BONDDEFINITIONS
  • EMPIRICAL FORMULA - LOWEST WHOLE NUMBER RATIO OF
    ELEMENTS IN A COMPOUND
  • MOLECULAR FORMULA SHOWS ACTUAL NUMBER AND KINDS
    OF ELEMENTS IN A COMPOUND
  • STRUCTURAL FORMULA SHOWS ARRANGEMENT OF ATOMS
    IN A COMPOUND

8
SINGLE COVALENT BOND
9
SINGLE COVALENT BOND
  • ELECTRON PAIRS REPRESENTED BY A LINE BETWEEN 2
    ELEMENTS
  • H - H
  • OTHER ELECTRONS MUST BE SHOWN, INCLUDING
  • UNSHARED PAIRS
  • LONE PAIRS
  • NON-BONDING PAIRS

10
2 CHLORINE ATOMS FORM A COVALENT BOND
  • SINGLE COVALENT BOND

11
WATER MOLECULE FORMED FROM 1 OXYGEN AND 2
HYDROGEN ATOMS USING COVALENT BONDS
  • SINGLE COVALENT BOND

12
SINGLE COVALENT BOND
  • CARBON FORMS UP TO 4 BONDS
  • C ?? ?? ?_ ?_
  • 1s 2s 2p
  • TO MAKE THE 4TH BOND, A 2s ELECTRON MOVES TO A
    2p ORBITAL
  • C ?? ?_ ?_ ?_ ?_
  • 1s 2s 2p

13
  • DOUBLE AND TRIPLE COVALENT BONDS

14
CORDINATE COVALENT BONDS
  • BOND FORMED WHEN BOTH ELECTRONS DONATED BY THE
    SAME ATOM

15
POLYATOMIC IONS
  • POLYATOMIC IONS ARE COVALENTLY BONDED
  • THE CHARGE ON THE ION SHOWS THE NUMBER OF
    ELECTRONS ADDED OR MISSING

16
RESONANCE
  • RESONANCE STRUCTURES SHOW 2 OR MORE VALID DOT
    FORMULAS HAVING THE SAME NUMBER OF BONDS AND
    ELECTRONS

17
EXCEPTIONS to the OCTET RULE
  • IN SOME MOLECULES, THE OCTET RULE CANNOT BE
    SATISFIED

18
EXCEPTIONS to the OCTET RULE
  • DIAMAGNETIC ALL ELECTRONS PAIRED
  • PARAMAGNETIC - 1 OR MORE UNPAIRED ELECTRONS
  • EXPANDED OCTET MAY INCLUDE MORE THAN 8
    ELECTRONS

19
MOLECULAR ORBITALS (MO)
  • WHEN 2 ATOMIC ORBITALS OVERLAP,
  • 2 MOLECULAR ORBITALS FORM
  • 1 ORBITAL IS BONDING
  • ENERGY LOWER THAN ATOMIC ORBITAL
  • 1 ORBITAL IS ANTI-BONDING
  • ENERGY HIGHER THAN ATOMIC ORBITAL
  • ORBITAL BELONGS TO MOLECULE AS A WHOLE
  • ORBITAL CONTAINS UP TO 2 ELECTRONS

20
MOLECULAR ORBITALS
Anti-bonding Molecular Orbital
Atomic Orbital
Atomic Orbital
Energy
Bonding Molecular Orbital
21
MOLECULAR ORBITALSHYDROGEN
  • TWO H2 MOLECULE ELECTRONS OCCUPY A BONDING
    ORBITAL
  • PROBABILITY OF FINDING ELECTRONS IN THE AREA
    BETWEEN 2 ATOMS IS HIGH
  • BOND IS SYMETRICAL ALONG AXIS BETWEEN ATOMS
  • CALLED A SIGMA (s) BOND

22
MOLECULAR ORBITALS
H2
Anti-bonding Molecular Orbital
Atomic Orbital
Atomic Orbital
?
?
Energy
??
Bonding Molecular Orbital
23
MOLECULAR ORBITALS (MO)
24
MOLECULAR ORBITALSHELIUM
  • 2 MOLECULES OF He CANNOT BE FORMED
  • 2 ELECTRONS IN BONDING ORBITAL
  • 2 ELECTRONS IN ANTI-BONDING ORBITAL
  • REPULSIVE FORCES IN ANTI-BONDING ORBITAL NEGATES
    ATTRACTIVE FORCES IN BONDING ORBITAL

25
MOLECULAR ORBITALS
He
Anti-bonding Molecular Orbital
??
Atomic Orbital
Atomic Orbital
??
??
Energy
??
Bonding Molecular Orbital
26
MOLECULAR ORBITALS
  • p ORBITALS CAN OVERLAP
  • OVERLAP END-TO-END SIGMA (s) BOND
  • OVERLAP SIDE-BY-SIDE PI (P) BOND

27
MOLECULAR ORBITALS
28
MOLECULAR ORBITALS
29
VALENCE SHELL ELECTRON PAIR REPULSION THEORYVSEPR
  • ELECTRON PAIRS REPEL DUE TO THE SAME CHARGE
  • MOLECULAR SHAPE ADJUSTS TO SET FURTHEST DISTANCE
    BETWEEN PAIRS
  • CREATES 3 DIMENSIONAL STRUCTURES

30
MOLECULES in 3-D
  • METHANE (CH4)
  • CARBON in CENTER, with H in the CORNERS to form a
    TETRAHEDRON
  • H-C-H ANGLES ARE 109.5

31
MOLECULES in 3-D
MOLECULAR GEOMETRY
32
MOLECULES in 3-D
  • UNSHARED ELECTRON PAIRS IMPACT SHAPE
  • UNSHARED ELECTRONS HELD CLOSER TO NUCLEUS
  • UNSHARED ELECTRONS ALSO MORE STRONGLY REPEL OTHER
    ATOMS
  • ANGLE SHIFTS TO 107

33
MOLECULES in 3-D
  • DIHYDROGEN OXIDE (H2O)
  • MOLECULE BECOMES BENT PLANAR WITH 2 PAIRS
    UNSHARED ELECTRONS
  • UNSHARED PAIRS REPEL BONDING PAIRS, COMPRESSING
    ANGLE
  • H-O-H ANGLE IS 105

34
MOLECULES in 3-D
  • CARBON DIOXIDE (CO2)
  • NO UNSHARED ELECTRON PAIRS IN CARBON DIOXIDE
  • MOLECULE IS LINEAR

ANGLE IS 180o
35
MOLECULES in 3-D
  • MOLECULES WITH NO UNPAIRED ELECTRONS, BUT WITH
    DOUBLE BOND
  • MOLECULE IS TRIAGONAL PLANAR SHAPE

36
HYBRID ORBITALS
  • SEVERAL ATOMIC ORBITALS CAN MIX TO FORM HYBRID
    ORBITALS
  • EACH ATOM HAS SEPARATE s AND p ORBITALS

37
HYBRID ORBITALS
  • SOME ATOMIC ORBITALS MERGE, FORMING 4 sp3 HYBRID
    ORBITALS
  • EACH ORBITAL BENDS TOWARD CORNER OF TETRAHEDRON

38
HYBRID ORBITALS
  • METHANE (CH4)
  • s ORBITALS OF HYDROGEN OVERLAP CARBON sp3
    ORBITAL
  • FORMS s BONDS

39
HYBRID ORBITALS
  • DOUBLE BONDS
  • ATOMIC ORBITALS IN DOUBLE BONDS MERGE TO FORM 3
    sp2 HYBRID ORBITALS 1 p ORBITAL REMAINS
  • ORBITALS BEND TOWARD CORNER OF TRIANGLE,
    PERPENDICULAR TO REMAINING p ORBITAL

40
HYBRID ORBITALS
  • ETHYLENE (C2H4)
  • HYDROGEN ORBITALS OVERLAP WITH CARBON sp2
    ORBITALS
  • 1 sp2 ORBITAL FROM EACH CARBON BONDS
  • REMAINING CARBON p ORBITALS FORM A P BOND

41
HYBRID ORBITALS
  • TRIPLE BONDS
  • ATOMIC ORBITALS MERGE TO FORM 2 sp HYBRID
    ORBITALS, AND 2 p ORBITALS REMAIN
  • ORBITAL IS LINEAR AND PERPENDICULAR TO REMAINING
    p ORBITALS

42
HYBRID ORBITALS
  • ACETYLENE (C2H2)
  • HYDROGEN s ORBITALS OVERLAP WITH CARBON sp2
    ORBITALS, AND 1CARBON sp2 ORBITAL EACH BOND
  • REMAINING CARBON p ORBITALS FORM P BOND

43
POLAR BONDS
  • BOND POLARITY
  • ELECTRONS SHARED IN COVALENT BOND
  • BUT NOT NECESSARILY EQUALLY
  • NON-POLAR BONDS
  • ELECTRONS SHARED EQUALLY
  • POLAR BOND
  • ELECTRONS PULLED STRONGLY TO ATOM WITH HIGHER
    ELECTRONEGATIVITY

44
POLAR BONDS
  • HYDROGEN IODIDE (HI)
  • IODINE (EN 2.5) HAS A HIGHER ELECTRONEGATIVITY
    THAN HYDROGEN (EN 2.1)
  • ELECTRONS DRAWN TOWARD IODINE NUCLEUS
  • REPRESENTED BY
  • d d-
  • H I or H - I
  • HYDROGEN DEVELOPS PARTIAL POSITIVE CHARGE, WHILE
    IODINE COUNTERS WITH A PARTIAL NEGATIVE CHARGE

45
POLAR BONDS
  • WATER AND CHLOROMETHANE ARE EXAMPLES OF POLAR
    MOLECULES

46
POLAR BONDS
  • TYPE OF BOND IS DETERMINED BY THE
    ELECTRONEGATIVITY OF THE BONDING ELEMENTS

Electronegativity Differences and Bond Type Electronegativity Differences and Bond Type Electronegativity Differences and Bond Type
Electronegativity Difference Type of Bond Example
0.0-0.4 Non-polar covalent H-H (0.0)
0.4-1.0 Moderately polar covalent H-Cl (0.9)
1.0-2.0 Very polar covalent H-F (1.9)
gt 2.0 Ionic NaCl- (2.1)
47
POLAR MOLECULES
  • POLAR MOLECULE HAS 1 OR MORE POLAR BONDS
  • CHARGED REGION IS A POLE
  • MOLECULE HAVING 2 POLES IS A DIPOLE
  • WHEN POLAR MOLECULES ARE PLACED IN AN ELECTRIC
    FIELD, THEY BECOME ORIENTED WITH RESPECT TO THE
    FIELD

48
POLAR MOLECULESIN AN ELECTRIC FIELD
Negative Plate
Positive Plate
49
POLAR MOLECULES
  • EFFECT OF POLAR BONDS ON THE MOLECULES POLARITY
    DEPENDS ON SHAPE OF THE MOLECULE AND POLAR BOND
    ORIENTATION
  • WATER IS A POLAR MOLECULE, BUT CARBON DIOXIDE IS
    NOT

50
BOND DISSOCIATION ENERGY
  • ENERGY NEEDED TO BREAK A COVALENT BOND

51
INTERMOLECULAR ATTRACTIONS
  • INTERMOLECULAR FORCES
  • DETERMINE COMPOUNDS PHYSICAL STATE
  • VERY WEAK COMPOUND IS A GAS
  • SOMEWHAT STRONGER COMPOUND IS A LIQUID
  • MUCH STRONGER COMPOUND IS A SOLID
  • MOLECULAR COMPOUND MELTING AND BOILING POINTS ARE
    LOWER THAN IONIC COMPOUNDS
  • MOLECULAR COMPOUNDS ARE INSOLUBLE IN WATER
  • MOLECULAR COMPOUNDS DO NOT CONDUCT ELECTRICITY IN
    THEIR LIQUID STATE

52
Van der Waals FORCES
  • DISPERSION FORCES
  • CAUSED BY ELECTRON MOTION
  • INCREASES AS ELECTRON NUMBER INCREASES
  • DIPOLE INTERACTIONS
  • ELECTROSTATIC INTERACTION BETWEEN OPPOSITE
    CHARGED REGIONS OF POLAR MOLECULES

53
HYDROGEN BONDING
  • CONDITIONS FOR HYDROGEN BONDING
  • COVALENT HYDROGEN BOND WITH HIGHLY
    ELECTRONEGATIVE ELEMENT
  • HYDROGEN WEAKLY BONDED TO UNSHARED ELECTRONDS IN
    ANOTHER MOLECULE
  • HYDROGEN BONDING OCCURS BECAUSE THERE IS NO
    SHIELDING EFFECT AROUND HYDROGEN NUCLEUS

54
IONIC COVALENT COMPOUND CHARACTERISTICS IONIC COVALENT COMPOUND CHARACTERISTICS IONIC COVALENT COMPOUND CHARACTERISTICS
Characteristics Ionic Compounds Covalent Compounds
Representative unit Formula Unit Molecule
Bond Formation Transfer of one or more electrons between atoms Sharing of electron pairs between atoms
Type of elements Metallic and non-metallic Non-metallic
Physical State Solid Solid, liquid or gas
Melting Point High (usually above 300 ?C) Low (usually below 300 ?C)
Solubility in water Usually high Usually low
Electrical conductivity of (aq) Good conductor Poor to non-conducting
55
COVALENT BONDING
  • THE END
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