Post on 16-Dec-2015
Lewis Dot Structures and
Molecular GeometryChapter 8 in online textChapter 15 in desk text
Why STUDY?
Warm-Up
What is the electron configuration of carbon?
How many valence electrons does Carbon have?
1s22s22p2
4
To determine the Lewis dot structure for Carbon we look at the number of valence electrons carbon has.
Carbon has four valence electrons and we represent electrons as DOTS.
C
Lewis Dot Structures for the first 10 elements on the periodic table.
Chemists use Lewis Dot Structures to determine how elements are covalently bonded to each other in a molecule.
• Covalently Bonded means to share electrons between elements. Sharing of electrons occurs between a nonmetal and another nonmetal.
• Single Bond- 2 electrons are shared• Double Bond- 4 electrons are shared• Triple Bond- 6 electrons are shared
Draw the Lewis Dot structure for BeF2.
1.Count the number of valence electrons you have to work with.Be F
Total : valence electrons
2. Put the least electronegative element in the center (remember the trend of E.N)**One exception: we never put Hydrogen in the center, because it can only make one bond.
3.Use pairs of electrons to form bonds between all atoms. (2 electrons make one bond)4.Use the remaining electrons to complete the octet rule for each element. (Exception: Be disobeys the octet rule it only has two valence electrons)
5.If you run out of electrons, you must introduce multiple bonds to maintain the octet rule. (BeF2 does not have multiple bonds-we will do more examples of this)
Let’s try to draw a Lewis Dot Structure of CO2 using the Rules1.Count the number of valence electrons you have to work with.
C O
Total : valence electrons
2. Put the least electronegative element in the center (remember the trend of E.N!!!?)
3.Use pairs of electrons to form bonds between all atoms. (2 electrons make one bond)4.Use the remaining electrons to complete the octet rule for each element.
5.If you run out of electrons, you must introduce multiple bonds to maintain the octet rule.
C OO
Let’s try NH3
Try these with a partner….
CH4
H2O
HCN
C
H
H
HH
H C N
Valence Shell Electron Pair RepulsionVSEPR
Electron pairs surrounding an atom want to be as far apart from each other as possible.
This gives rise to different molecular shapes.
The simplest shape is a LINE
Alkali Metals and Halogens make a line because they can only bond once.
Groups 1 and 17 make a line
Let’s look at another simple molecular shape
The electron pairs are the farthest apart they can be.
This molecule is LINEAR The center atom bonds twice.
Elements in group 2 make linear structures.
How is the Be atom able to covalently bound to the fluorines?
Hybridization of the orbitals explains this.
Two or more of the orbitals of the central atom must mix to form new orbitals of equal energy so bonding can take place.
2s
2p
Hybrid mixing
s p
A linear molecule has sp hybridization
Fill in valence electrons
Trigonal Planar Shape
BH3
Draw Lewis Structure:
This arrangement lets all the electron pairs be the furthest apart from each other.
Group 13 makes a trigonal planar shape
Draw electron diagram for B
Hybrid mixing
2s
2p s p p
A trigonal planar molecule has a sp2 hybridization
TetrahedralCH4 Methane
Structure:
This arrangement lets all the electron pairs be the furthest away from each other.
Group 14 makes tetrahedral shapes.
What does the word ‘tetra’ mean?
Draw the electron diagram of Carbon
What do you think is the hybridization of tetrahedral molecules??
2s
2p
Trigonal Pyramidal
NH3
This arrangement lets all the electron pairs be the furthest apart from each other. With one lone pair.
This is similar to the tetrahedral arrangement ,but has one lone pair.
Group 16 makes Trigonal Pyramidal Shapes
2s
2p
What is the hybridization of NH3( trigonal pyramidal)
Fill in valence electrons for Nitrogen
Bent shape
H2O
This arrangement lets all the electron pairs be the furthest apart from each other. With two lone pairs.
What is the hybridization of the bent molecule? Do you think it will be similar to tetrahedral?
Group 15 makes bent shapes.
What is the hybridization of H20? (bent shape)
2s
2p
Fill in valence electrons for oxygen
VSEPR Theory Summary
Linear 2 sp CO2
Trigonal Planar
3 sp2 BH3
Tetrahedral 4 sp3 CH4
Trigonal Pyramidal
3 with one lone pair
sp3 NH3
Bent 2 with two lone pairs
sp3 H2O
Shape #of atoms Hybridization Examples
Group 2
Group 13
Group 14
Group 15
Group 16
In some covalent bonds electrons are not shared equally between the elements.
The more electronegative element ‘WINS’ the electrons.
The charge difference across the bond as well as the shape of the molecule results in a POLAR Molecule.
Polarity of MoleculesWe can determine if a molecule is polar or nonpolar by the
molecule’s shape.
Polarity of Water
Lets take water for example:
Polar molecules act as tiny dipoles because they have un even charges.
A dipole is created by equal but opposite charges that are separated by a short distance.
Direction of dipole is from positive end to more negative end (more electronegative element)
Because WATER is a BENT Molecule the polarities of each bond add together to make this molecule highly
POLAR
What about NH3 Trigonal PyramidalPOLAR OR NONPOLAR?
The dipoles of the three bonds are additive combining to form an overall net dipole
Because NH3 is trigonal pyramidal shape it is POLAR
CH4
CO2
The individual bond polarities extend equally and symmetrically in different
directions canceling out . OVERALL the molecules are NONPOLAR.
What about CH3Cl? NonPolar or Polar?
Try with a partner…
Cl
H
H
H
POLAR