faculty.kfupm.edu.safaculty.kfupm.edu.sa/.../chem101/Slides/Chapter8.docx · Web viewBorn-Haber...
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Chapter 8Chemical Bonding I: Basic Concepts
8.1 Lewis Dot Symbols:
• Valence electrons determine an element’s chemistry.
• Lewis dot symbols represent the valence electrons of an atom as dots arranged around the atomic symbol.
• Most useful for main-group elements
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Write Lewis dot symbols for the following:
N
S2
K+
K+
N•••
••
••
•• S ••
••2
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8.2 Ionic Bonding:
• Ionic bond: electrostatic force that holds oppositely charge particles together
• Formed between cations and anions
Example:
m.p. = 801oC and fH = – 410.9 kJ/mol
Na• Cl•••••
••+ Na+ Cl••••
•• •• +
IE1 + EA1 = 496 kJ/mol 349 kJ/mol = 147 kJ/mol
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Microscopic View of NaCl Formation
• Lattice energy = the energy required to completely separate one mole of a solid ionic compound into gaseous ions
• NaCl(s) ® Na+(g) + Cl(g) Hlattice = +788 kJ/mol
• (Lattice energies are always positive)
+
--
-
--
-
-- ++
+++
+
+
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Coulombic attraction:
When two charges Q1 and Q2 are separated by a distance d
The electrostatic force between the two charges is defined as:
When, Q1 and Q2 are similar F is repulsive force
Q1 and Q2 are different F is attractive force
• Lattice energy (like a coulombic force) depends on
• Magnitude of charges
• Distance between the charges
Q1
F∝Q1⋅Q2
d2
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Lattice energies of alkali metal iodides:
F is inversely proportional to the distance between the charges
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The ionic radii sums for LiF and MgO are 2.01 and 2.06 Å, respectively, yet their lattice energies are 1030 and 3795 kJ/mol. Why is the lattice energy of MgO nearly four times that of LiF?
F is directly proportional to the product of the charges
(The product of the charges in LiF is half of that in MgO)• Born-Haber cycle :
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A method to determine lattice energies
• Lattice energy = the energy required to completely separate one mole of a solid ionic compound into gaseous ions
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• NaCl(s) ® Na+(g) + Cl(g) Hlattice = +788 kJ/mol
• NaCl(s) Na+(g) + Cl(g) Hlattice = -788 kJ/mol
Born-Haber cycle for CaO
Ca(s) + (1/2) O2(g)® CaO(s)
Ca(g)1
1 Heat of sublimation = Hf[Ca(g)] = +178 kJ/mol Ca2+(g)
2
2 1st & 2nd ionization energies = I1(Ca) + I2(Ca) = +1734.5 kJ/mol
O(g)3
3 (1/2) Bond enthalpy = (1/2) D(O=O) = Hf[O(g)] = +247.5 kJ/mol
O2(g)4
4 1st & 2nd electron affinities = EA1(O) + EA2(O) = +603 kJ/mol
+5
5 (Lattice Energy) = Hlattice[CaO(s)] = (the unknown)
6
6 Standard enthalpy of formation = Hf[CaO(s)] = 635 kJ/mol +178 +1734.5 +247.5 +603 Hlatt = 635Hlattice = +3398 kJ/mol
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8.3 Covalent Bonding:
• Atoms share electrons to form covalent bonds.
or H–H
• In forming the bond the atoms achieve a more stable electron configuration.
• Octet Rule : Atoms will gain, lose, or share electrons to acquire eight valence electrons
Na• Cl•••••
••+ Na+ Cl••••
•• ••
+
Examples:
H• •O•••••H• O••••
•••• HH+ +
•HH• + ••H H
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Lewis Structures:
•HH• + ••H H H–H
Cl•••••
••+Cl•••••
•• Cl••••
•• •• Cl••••
•• Cl••••
•• Cl••••
••–
Shared electrons BondsNon-bonding valence electrons Lone pairs
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Multiple Bonds:
- The number of shared electron pairs is the number
of bonds.
Bond strength and bond length:
bond strength single < double < triple
bond length single > double > tripleN–N N=N NN
Bond Strength163 kJ/mol418 kJ/mol941 kJ/molBond Length1.47 Å 1.24 Å 1.10 Å
Cl••••
•• •• Cl••••
•• Cl••••
•• Cl••••
••– Single Bond
O•••• C
•• •• •••• O•••• O•••• O••••=C= Double Bond
••••N
•• •• ••N N
•• ••N Triple Bond
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8.4 Electronegativity and Polarity:
• Nonpolar covalent bond = electrons are shared equally by two (similar) bonded atoms
• Polar covalent bond = electrons are shared unequally by two (different) bonded atoms
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Electronegativity: ability of an atom to draw shared electrons to itself.
- More electronegative elements attract electrons more strongly.
relative scale
related to IE and EAunitless
smallest electronegativity: Cs 0.7
largest electronegativity: F 4.0
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Electronegativity: The Pauling Scale
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Electron density distributions:
red high electron densitygreen intermediate electron densityblue low electron density
+ -
H – F
alternaterepresentat
ions
H – F
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Polar and nonpolar bonds:
2.1 - 2.1 = 0.0 4.0 - 2.1 = 1.9 4.0 - 0.9 = 3.1
nonpolarcovalent
polarcovalent ionic
> 2.0 is ionic
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Dipole moments and partial charges:
- Polar bonds often result in polar molecules.
- A polar molecule possesses a dipole.
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See Problem 8.5:
- dipole moment () = the quantitative measure of a dipole
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8.5 Drawing Lewis Structures:
The Lewis structure of a molecule shows how the valence electrons are arranged among the atoms in the molecule.
From experiment, it was shown that in forming a stable compound, atoms try to achieve noble gas electron configuration [8 electrons (lone-pairs plus bonding shared electrons) around each atom of the molecule].
Rules for writing Lewis structures:
1) Sum the valence electrons from all the atoms.
2) Use a pair of electrons to form a bond between each pair of bound atoms. Form multiple bonds when it is necessary (e.g. CO2 and O3).
3) Arrange the remaining electrons to satisfy the octet rule (form single bonds for hydrogen).
4) If any electrons remain place them in pairs on the central atom {e.g (NO3)-}.
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Examples:
1. H2O (water): 1H and 8O 1H and 8O
Sum of valence electrons = 1 + 1 + 6 = 8
H−O. .
. .−H
2. CO2 (carbon dioxide): 6C and 8O
Sum of valence electrons = 4 + 6 + 6 = 16
O. .
. .=C=O
. .
. .
3. CN- (Cyanide ion): 6C and 7N
Sum of valence electrons = 4 + 5 + 1 = 10
[CN]-
4. NO+ (Nitrogen oxide ion) 7N and 8O
Sum of valence electrons = 5 + 6 – 1 = 10
[NO]+
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5. N2 (Nitrogen) 7N and 7N
Sum of valence electrons = 5 + 5 = 10
NN
6. Cl3-
Sum of valence electrons = 3 x 7 + 1 = 22
( :Cl
. .
. .−Cl
. .
.. . .−Cl
. .
. .:)−
Note that there is 3 lone-paris of electrons around
the central Cl atom. This is a case of exception
that will be discussed in sec. 8.8.
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7. What is the Lewis structure of NO3 ?
1) Draw skeletal structure with central atom being the least electronegative.
OO – N – O
–
4) Complete electron octets for atoms bonded to the central atom except for hydrogen.
:O::O – N –O:
–:
:
::
:
18 e
–6) Add multiple bonds if
atoms lack an octet. :O:
:O – N = O:
– :
::
:
24 e
5) Place extra electrons on the central atom.
2) Sum valence electrons. Add 1 for each negative charge and subtract 1 for each positive charge.NO3
(1 5) + (3 6) + 1 = 24 valence e 24 e
3) Subtract 2 for each bond in the skeletal structure. 6 e
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8.6 Lewis Structures and Formal Charge:
Formal Charge:
The formal charge of an atom in a molecule is the difference between the number of valence electrons on the free atom and the number of valence electrons assigned to the atom in a molecule.
Rules for Determining Formal Charges:
1. Take the sum of the lone-pair electrons and one half the shared electrons.
2. Subtract the number of assigned electrons from the number of valence electrons on the free atom.
3. The sum of the formal charges of all atoms equals the overall charge.
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Example: Formal charges on the atoms in ozone:
v.es.f.a l.p.es sh.es/2
6 4 12 4
06 2 1
2 6 16 6 1
2 2 1
O
O
O
O OO
Formal charge guidelines :
− A Lewis structure with no formal charges is generally better than one with formal charges.
− Small formal charges are generally better than large formal charges.
− Negative formal charges should be on the more electronegative atom(s).
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Identify the best structure for formaldehyde below:
Identify the best structure for the isocyanate ion below:
Structure (b) is best structure of isocyanate ion
(a) :C = N = O:
: –
:C N – O:
::
–
(c)
(b)
:C – N O:
::
–
2 +1
3
+1
+1 +1
1 1
0
H C O H•• •• +
C O
H
H
••••
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8.7 Resonance:
Two resonance structures, their average or the resonance hybrid, best describes the nitrite ion.
:O – N = O:
:
:: : –
:O = N – O:
::
: : –Solution:
The double-headed arrow indicates resonance.
:O – N = O:
:
:: : –
These two bonds are known to be identical.
Resonance structures are used when two or more equally valid Lewis structures can be written.
Example: NO2
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Benzene: C6H6
Additional Examples
Carbonate: CO32
or
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8.8 Exceptions to the Octet Rule:
Exceptions to the octet rule fall into three categories:
− Molecules with an incomplete octet
− Molecules with an odd number of electrons
− Molecules with an expanded octet
Incomplete Octets:
Example: BF3 (boron trifluoride)BF3 (1 3) + (3 7) = 24 val. e
:F::F – B = F:
–:
:
::
+1-1
Common with Be, B and Al compounds, but they often dimerize or polymerize.
Example:Cl Cl Cl
Be Be Be BeCl Cl Cl
:F::F – B – F:
–:
::
::
no octet
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Odd Numbers of Electrons:
Example: NO2 (nitrogen dioxide)
NO2 (1 5) + (2 6) = 17 val. e
:N = O:.
:N = O:. Are these
both equally good?
:O = N – O:.:O – N = O:
.:O = N – O:
.
Are these all equally good?
better
0 0 1 +1
0 0 0 0 0 0 0 +1 1 1 +1 0
best
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Expanded Octet:
− Elements of the 3rd period and beyond have d-orbitals that allow more than 8 valence electrons.
P
Cl
Cl
ClCl
Cl
::
::
: ::
..
..
......
.... : 40 electrons
XeF2 = :F – Xe – F:::
: ::
(Xe has 10 valence electrons)
22 valence e
(S has 12 valence electrons )
F FS
F F
:F:–
–
:F:
SF6 = 48 valence e
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8.9 Bond Enthalpy:
• Bond enthalpy is the energy associated with breaking a particular bond in one mole of gaseous molecules.
HCl(g) ® H(g) + Cl(g) Ho = 431.9 kJ
Cl2(g) ® Cl(g) + Cl(g) Ho = 243.4 kJ
O2(g) ® O(g) + O(g) Ho = 495.0 kJ
N2(g) ® N(g) + N(g) Ho = 945.4 kJ
single bonds
double bond
triple bond
For diatomic molecules these are accurately measured quantities.
Bond enthalpy is one measure of molecular stability.
Symbol: Ho
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− Bond enthalpies for polyatomic molecules depend upon the bond’s environment.
− Average bond enthalpies are used for polyatomic molecules.
H = 410 kJ6% less
® + H
H
H – C
H –
–
H
– C – H
H
––
H
H – C
H
––
H
– C
H
––
H = 435 kJ
H
H – C – H
H
––
H
H – C
H
––
® + H
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Prediction of bond enthalpy:
Ho = BE(reactants) BE(products)
(BE = bond energy)
reactants
atoms
products
BE(r)
BE(p)
enth
alpy
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Example: Calculate the enthalpy of reaction forCH4(g) + Br2(g) ® CH3Br(g) + HBr(g)
Solution: Consider ONLY bonds broken or formed.
H
H – C – H
H
––
Br – Br H – Br++
H
H – C – Br
H
––
®
Hrxn = [ BE(C–H) + BE(Br–Br) ] – [ BE(C–Br) + BE(H–Br) ]
= [ (413) + (193) ] – [ (276) + (366) ]
= – 36 kJ/mol
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