Title: 14'1 Shapes of molecules and ions HL
114.1 Shapes of molecules and ions (HL)
- 14.1.1 State and predict the shape and bond
angles using the VSEPR theory for 5 and 6
negative charge centers.
2Molecules with more than 4 electron pairs
- Molecules with more than 8 valence electrons
expanded valence shell - Form when an atom can promote one of more
electron from a doubly filled s- or p-orbital
into an unfilled low energy d-orbital - Only in period 3 or higher because that is where
unused d-orbitals begin
3Why does this promotion occur?
- When atoms absorb energy (heat, electricity,
etc)their electrons become excited and move from
a lower energy level orbital to a slightly higher
one. - How many new bonding sites formed depends on how
many valence electrons are excited.
4- Exceptions to the octet rule. Shows sulphur
achieving 8, 10 and 12 valence electrons due to
energy input and excited electrons. - http//www.saskschools.ca/curr_content/chem20/covm
olec/exceptns.html
5Trigonal Bipyramidal (5 pairs of V.E.)
6Trigonal Bipyramidal
- Normally would have 3 bp, but the lone pair has
moved from the p-orbital to include the
d-orbital, allowing for 2 additional bonding
sites. - Ex PCl5
7Octahedral (6 pairs of V.E.)
8BrF5 is square pyramidal
SF6 is octahedral
XeF4 is square planar
9Bond angles
- In general, the greater the bond angle, the
weaker the repulsions. - Equatorial- equatorial (120 o) repulsions are
weaker than axial- equatorial (90o) repulsions. - Equatorial lie on the trigonal plane (straight
across) - Axial lies above and below the trigonal plane
(up and down)
10- Remember that lone pairs cause more repulsion
than bonding sites, so expect the bond angle to
be changed should there be lone pairs, or double
or triple bonds involved (multiple bonds also
cause more repulsion than expected)
11Practice
- ClF3
- PF5
- XeO2F2
- SOF4
- SCl6
- IF4
- ICl4-
- T-shaped
- Trigonal bipyramidal
- Seesaw
- Trigonal bipyramidal
- Octahedral
- Seesaw
- Square planar
1214.2 Hybridization.
- 14.2.1 Describe s (sigma) and p (pi) bonds
- 14.2.2 State and explain the meaning of the term
hybridization - 14.2.3 Discuss the relationships between Lewis
structures, molecular shapes and types of
hybridization (sp, sp2, sp3).
13hybridization
- the concept of mixing atomic orbitals to form new
hybrid orbitals - Used to help explain some atomic bonding
properties and the shape of molecular orbitals
for molecules. - The valence orbitals (outermost s and p orbitals)
are hybridised (mathematically mixed) before
bonding, converting some of the dissimilar s and
p orbitals into identical hybrid spn orbitals - We must know sp, sp2, and sp3 hydrid orbitals
14Hybrid orbitals
- Carbon has 4 valence electrons.
- 2 electrons paired up in the s-orbital, and 2
electrons unpaired in the p-orbital. - So why does it commonly make 4 bonding sites?
15- One of carbons paired s-orbital electrons is
promoted to the empty p-orbital - This produces a carbon in an excited state which
has 4 unpaired electrons (4 equivalent bonding
sites)
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17sp3 hybrid orbital
- formed by mixing the outermost s- and all three
outermost p- orbitals to form four sp3 hybrids. - The furthest these four negatively charged, and
therefore repulsive orbitals can get from each
other is the corners of a tetrahedron (109).
18Overlap four s-orbitals from four hydrogens
(blue) with four sp3 hybrids on carbon leads to
formation of bonds, each containing one electron
from the carbon and one from the hydrogen
19Examples of sp3 hybrids
- Methane, ammonia, water and hydrogen fluoride.
- Note that the orbitals not involved in bonding to
hydrogen are still hybridised, but end up as lone
pairs of electrons (symbolised by the two dots in
the diagram above).
20sp2 hybrid orbital
- formed when only one s- and two p-orbitals are
involved. - This leaves one remaining p orbital, which may be
involved in forming a double bond.
21- The furthest these orbitals can get from one
another is a trigonal bipyramid, with the sp2
hybrids arranged at 120 to each other in a
plane. - This is characteristic of molecules with double
bonds.
22- Finally, sp hybrids are formed using just one s
and one p orbital. - Two sp hybrids are formed from them, and the two
p-orbitals remaining may contribute to a triple
bond. - These arrange themselves at the corners of an
octahedron, with the two sp hybrids diametrically
opposite one another. - sp hybridisation is characteristic of the triple
bond. (1 s-bond and 2 p (pi) bonds)
23Sigma bond (s-bond)
- When s and/or hybrid orbitals overlap 'end-on',
sigma bonds (s) are formed - They have a single area of electron density
between the nuclei of the two atoms whose
orbitals are overlapping. - In the diagrams below, s bond is shown
24Sigma bond (s-bond)
- results from head-on overlap of orbitals
- electron density is symmetric about the
internuclear axis between nuclei.
25p (pi) bonds
- p orbitals can overlap sideways too when this
happens two lobes of electron density are formed
between the atoms. - From the diagram, you can see that the double
bond in ethene is composed of one s plus one p
bond,
26p (pi) bonds
- results from sideways overlap of orbitals
- bonds resulting from the combination of parallel
p orbitals - electron density is above and below the
internuclear axis.
27Predicting shape
- The shape is dictated by the s-bonds and the
non-bonding electron pairs (lone pairs) - p-bonds do not affect the shape of the molecule
(double bonds or triple bonds) - Thats why we refer to bonding sites when using
VSEPR, not paying attention to whether it was
single, double or triple bonded.
2814.3 Delocalization of electrons
- 14.3.1 Describe the delocalization of (pi) p-
electrons and explain how this can account for
the structure of some species
29Delocalised electrons
- The term 'delocalised' refers to an electron
which is not 'attached' to a particular atom or
to a specific bond. - Delocalized electrons are contained within an
orbital that extends over several adjacent atoms.
- Classically, delocalized electrons can be found
in double bonds and in aromatic systems - Double bonds 1 sigma and 1 pi bond
- Delocalisation is often represented with
resonance structures or resonance hybrid
30Resonance structures
- the nitrate ion can be viewed as if it resonates
between the three different structures above. - Nitrate doesnt change from one to the next, but
behaves as a combination of all structures
31- Resonance is possible whenever a Lewis structure
has a multiple bond and an adjacent atom with at
least one lone pair. - The following is the general form for resonance
in a structure of this type.
32Practice
- Try to show the individual Lewis structures for
the HCO3- ion - Show its resonance structure too
33Practice drawing these resonance structures
- NO3-
- NO2-
- CO32-
- O3
- RCOO-
- Benzene (C6H6)
- TOK
- Kekule claimed that the inspiration for the
cyclic structure of benzene came from a dream. - What role do the less rational ways of knowing
play in the acquistion of scientific knowledge?
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35Bibliography and sites to visit
- http//www.tutorvista.com/content/chemistry/chemis
try-iii/chemical-bonding/types-covalent-bonds.php - Good site on types of covalent bonds
- http//www.mikeblaber.org/oldwine/chm1045/notes/Ge
ometry/VSEPR/Geom02.htm - Used for expanded valence shell pictures
- http//www.kentchemistry.com/links/bonding/lewisdo
tstruct.htm - Puts the lewis diagrams together and explain
them. Including expanded shell
36- http//www.mpcfaculty.net/mark_bishop/resonance.ht
m - Resonance structures pictures and notes
- http//en.wikipedia.org/wiki/Delocalization
- Notes on delocalisation of electrons
- http//www.steve.gb.com/science/atomic_structure.h
tml - Amazing website for hybrid orbitals
- http//library.thinkquest.org/C006669/data/Chem/bo
nding/shapes.html - Good review of all shapes