chm012_Topic 2 - Chemical Bonding.pdf

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CHM012
Chemistry for
Engineers Topic 2:
Chemical Bonding
Department of Chemistry
College of Science and Mathematics
MSU-Iligan Institute of Technology

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 Questions to Consider
❖ What is meant by the term “chemical bond”?
❖ Why do atoms bond with each other to form compounds?
❖ How do atoms bond with each other to form compounds?

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 Types of Chemical Bond
⮚ Chemical bond – force of attraction that binds atom together in a given molecule

⮚ Types:
1. Covalent – between two non-metal atoms (ex. CH4)
2. Ionic – between a metal and a non-metal atoms (ex. KCl)
3. Metallic – between metal atoms

⮚ Molecules can be represented using:

✔ Chemical Formula ✔ Space-filling model: Indicates the
relative sizes of the atoms as well
CH4 as their relative orientation in the
molecule
✔ Structural Formula
✔ Ball and stick method: A three-
dimensional model using spheres
and rods

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 Ways of Gaining Stability
”Atoms interact to gain stability by changing the outermost
configuration to become isoelectronic to a noble gas.”

- G.N. Lewis (1916) -

1. Sharing electrons (Covalent bonding)
2. Transferring electrons (Ionic Bonding)

✔ Atoms that form covalent bonds are non-metals or elements that has high ionization energy or ionization
potential.
✔ Ionic bonds occurs between an atom that easily loses electrons (low ionization energy) and an atom that has a
high affinity for electrons

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 Lewis Symbol
⮚ G. N. Lewis developed a method to denote potential bonding electrons by using one dot for every valence electron
around the element symbol.

⮚ When forming compounds, atoms tend to gain, lose, or share electrons until they are surrounded by eight valence
electrons (the octet rule).

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 Lewis Symbol

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 Ionic Bond Formation
✔ Atoms tend to lose (metals) or gain (nonmetals) electrons to make them isoelectronic to the noble gases.

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 Energetics of Ionic Bonding – Born-Haber Cycle
✔ Many factors affect the energy of ionic bonding.
✔ Start with the metal and nonmetal elements: Na(s)
and Cl2(g).
✔ Make gaseous atoms: Na(g) and Cl(g).
✔ Make ions: Na+(g) and Cl–(g).
✔ Combine the ions: NaCl(s).

We already discussed making ions (ionization energy
and electron affinity).
✔ It takes energy to convert the elements to atoms.
(endothermic)
✔ It takes energy to create a cation (endothermic).
✔ Energy is released by making the anion (exothermic).
✔ The formation of the solid releases a huge amount of
energy (exothermic).
✔ This makes the formation of salts from the elements
exothermic.

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 Lattice Energy
⮚ That huge, exothermic transition is the
reverse of the lattice energy, - the energy
required to completely separate a mole of
a solid ionic compound into its gaseous
ions.

⮚ The energy associated with electrostatic
interactions is governed by Coulomb’s
law:

⮚ Lattice energy increases with:
– increasing charge on the ions
– decreasing size of ions

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 Covalent Bond Formation
⮚ In covalent bonds, atoms share electrons.

⮚ There are several electrostatic interactions in these bonds:
✔ attractions between electrons and nuclei,
✔ repulsions between electrons, and
✔ repulsions between nuclei.

⮚ For a bond to form, the attractions must be greater than the repulsions.

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 Types of Covalent Bonds
1. Based on donor atom
a. Normal covalent bond – a bond formed when each atom donates an electron.

a. Dative or coordinate covalent bond – only one (1) atom donates the electron pair to form a bond.

+ H+

2. Based on electronegativity of the bonded atoms.
a. Non-polar covalent bond – when atoms bonded has almost the same electronegativities.
H – H (H2) , O = O (O2) , C – H (CH4)

a. Polar covalent bond – having different electronegativities.

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 Electronegativity
⮚ Electronegativity is the ability of
an atom in a molecule to attract
electrons to itself.

⮚ On the periodic table,
electronegativity generally
increases as you go
✔ from left to right across a
period.
✔ from the bottom to the top
of a group.

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 Polar Covalent Bonds
✔ The electrons in a covalent bond are not
always shared equally.

✔ Fluorine pulls harder on the electrons it
shares with hydrogen than hydrogen does.

✔ Therefore, the fluorine end of the molecule
has more electron density than the hydrogen
end.

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 Polar Covalent Bonds
⮚ When two atoms share electrons unequally, a polar covalent bond results.
⮚ Electrons tend to spend more time around the more electronegative
atom. The result is a partial negative charge (not a complete transfer of
charge). It is represented by δ–. The other atom is “more positive,” or δ+.
⮚ The greater the difference in electronegativity, the more polar is the
bond.

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 Points to Note

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 Lewis Structure
Basic concepts
⮚ Duet, octet, expanded octet
⮚ Covalency – the number of bonds formed by an atom in forming a molecule.

normal covalency – the number of electrons needed by an atom to have an octet of electrons.

Group No. IV V VI VII
Element Carbon Nitrogen Oxygen Fluorine
Lewis
Symbol
Normal
covalency* 4 3 2 1
*obeyed by 2nd period elements only.

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 Lewis Structure
Simple guidelines in Lewis Structure writing:
1. Determine the total number of valence electrons
e.g. SO2 : 6 x 3 = 18 e-
SO32- : (6 x 4) + 2 = 26 e-
NH4+ : (5 + 4) -1 = 8 e-

2. Determine the central atom.
⮚ the central atom must have the highest normal covalency.
⮚ if the same normal covalency, the less electronegative atom is the central atom.

3. Write the skeletal structure using single bonds to join two (2) atoms.

4. Count the number of electrons for each atoms:
⮚ 2nd period elements must have octet.
⮚ 3rd period and above can have expanded octet.
⮚ All outer atoms obey the octet rule.

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 Lewis Structure
5. Introduce multiple bond whenever the octet rule is not satisfied.

6. If the substance has a charge, enclose the Lewis Structure with a bracket [] and indicate the charge.
e.g. 1+, 2+, 3+, 3-, etc.

7. For an AXX molecule, where all atoms obey the octet rule, use Langmuir formula to determine the number of
covalent bonds formed.

example: NO2-

Total No. of e- : 5 + 2 (6) + 1 = 18 e-

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 Exceptions to the Octet Rule
✔ Boron tends to form compounds in which the boron atom has
fewer than eight electrons around it.
✔ It does not have a complete octet
✔ The Lewis structure of boron fluoride
✔ Boron has only 6 electrons around it
✔ Adding a double bond satisfies the octet rule

❖ In stable compounds such as H3NBF4, boron has an octet of electrons

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 Exceptions: Expanded Octet
✔ Observed only in elements in Period 3 of the periodic
table and beyond
✔ Consider the Lewis structure of sulfur hexafluoride:
6 + 6 (7) = 48 electrons

✔ When it is necessary to exceed the octet rule for one
of several third-row (or higher) elements, assume that
the extra electrons should be placed on the central
atom
✔ Calculating the valence electrons present in the
triiodide ion (I3−)
3(7) + 1 = 22 valence electrons

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 Importance of Lewis Structure
1. Determination of formal charges of atoms.
2. Determination of geometry of molecules or ions.

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 Formal Charge
⮚ Formal Charge - it is an indication of the charge an atom would carry if it shared the electrons in a covalent bond
equally.

Assumptions:
1. There is equal sharing of electron pair in a given bond.
2. 100% covalent character
3. Polarity of the bond is NOT considered.
4. It does not represent the actual charge distribution.
5. It is dependent on the Lewis Structure.

G = Group no.
U = No. of unshared e-
C = No. of covalent bonds

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 Formal Charge
⮚ Guidelines in determining FC:
1. For atoms obeying the octet rule
a. In a given Lewis Structure, if an atom exhibits its normal covalency, then FC = 0
b. If the atom exceeded its normal covalency then its FC is positive (+)
c. If the atom has less no. of bonds compared to its normal covalency, then its FC is negative (-)

2. The sum of all the FC must be equal to the net charge of the ion. If there is no charge, then the sum is equal to
zero (molecule).

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 Example
⮚ Example: SO3 1-
No. of e- = 24 e-

1-
2+

⮚ Example: ClO4-
No. of e- = 32 e-
-

[
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 Importance of Formal Charge

Formal Charge (-1) (+1)

Electronegativity

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 Resonance
⮚ Some molecules or ions can be represented by several Lewis structures/valence bond formulas.

Note: Localized bonds – refers to single bonds
Delocalized bonds – refers to multiple bonds

e.g. CO32-

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 Resonance
Guidelines on determining important Contributing Structures, C.S.
1. C.S. must have the same atomic positions, they may only differ on the positions of e- (when writing C.S. do not
change the relative position of the atomic nuclei.)

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 Resonance

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 Resonance
4. Position of formal charges distribution
✔ Adjacent like charge is unfavorable (less important)
✔ Adjacent opposite charge is favorable (more important)

✔ Important
✔ Important
✔ Reasonable distribution of
✔ Adjacent opposite
FC.
charge
✔ Adjacent opposite charge

✔ Less important due to
adjacent like charge

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 Resonance
5. Electroneutrality principle
✔ A C.S. where all atoms have zero formal charge will be the most stable, therefore more important.

-1 -1 +1 -2

✔ Important ✔ Most important ✔ Less important
✔ Two atoms has zero ✔ Reasonable charge ✔ One atoms has zero
formal charge distribution formal charge
✔ Two atoms has zero
formal charge

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 Resonance
6. The greater the number of covalent bonds, the greater the importance of the C.S.

(4) (3) (2) (1)

increasing importance of contributing structure

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