Bonding & Molecular Structure Physical Science K Warne
Dec 16, 2015
Bonding & Molecular Structure
Physical Science
K Warne
Atoms and molecules (simple and giant)Carry out all of the following tasks with respect to the following elements & compounds: oxygen, water, petrol, sugar, carbon (diamond & graphite), table salt and copper metal.
· Find out which of these (or any other) substances found in atomic form.
· Define a molecule.
· Write formula for each of these substances using:
o Molecular formula for simple molecules
o Empirical formulae for giant molecules
· Draw these molecules showing both space filling and ball and stick representations.
· Group these substances into:
o Simple molecules (relatively few atoms per molecule):
o Giant molecules (millions of atoms per molecule):
Describe the difference between inter and intra molecular forces. State which of these forces are involved in phase changes. Explain the boiling point of water in relation to the other hydrides of group six.
. · Link the macroscopic properties of these substances to their microscopic (particle) structure.
• Two different types of bonds occur in water.
• Intramolecular– Between hydrogen
atoms and oxygen atoms inside the molecules Covalent bonds
• Intermolecular– Between two
different water molecules Hydrogen bonds
Intermolecular forces
O+
-H
HO+ -
H
H
O+
-
H
H
Bond Polarity in Water
The oxygen atom has greater electronegativity so it is surrounded by greater electron density than the hydrogen atoms. O
H
H
-
+
++ -
The water molecule is a DIPOLE - it has two oppositely charged “poles”.
OH
H+ -
• The oppositely charged poles on the water molecules attract each other.
• This electrostatic attraction constitutes Hydrogen bonding.
• It is the strongest form of intermolecular attraction.
• Hydrogen bonding exists only between molecules in which hydrogen is bonded to a very electronegative atom (H-O-X, H-NX2 or H-F).
• Result in abnormally high boiling points.
Hydrogen Bonding
O+
-H
HO+ -
H
H
O+
-
H
H
Example:Water
Molecular solids
Iodine - I2
Strong covalent bonds
Weaker intermolecular bonds
Covalently bonded molecules held together by weaker intermolecular bonding.
PROPERTIES
• Low melting points
• Brittle
• Soluble in non-polar solvents
• Non - conducting
IMF vs Mp & BpHalogenX2 (diatomic)
Molecular
Mass (Mr g.mol-1)
Mp / Bp (oC)
FlourineF2 pale yellow gas
19 x 2 =
38 -220 / -188
ChlorineCl2 pale green gas
35.5 x 2 =
71-101/ -35
BromineBr2 red volatile liquid
80 x 2 =
160-7 / 59
IodineI2 purple solid - sublimes
127 x 2 =
254114 / 184
Mp
& B
p in
crea
ses
with
SIZ
E
and
mol
ecul
e M
AS
S
. .: X .
. .
. .: X .
. .
Density
Density = mass/volume (g.cm-3)
High density – solids
Many particles per cm3
Low density – gases
Few particles per cm3
1cm x 1cm x 1cm = 1cm3
Effect of Temp
• Temperature is a measure of average kinetic energy.• As temperature rises more particles have high energy.
Maxwell-Boltzman Curve
Average Ek
Increases
Effect of Temp
• Temperature is a measure of average kinetic energy.• As temperature rises – particles move faster – and further apart –
substances expand – used in a thermometer.
Maxwell-Boltzman Curve
Average Ek
Viscosity• Viscosity is a measure of
how thick (viscous) and sticky a liquid is.
• Viscosity reduces the ability of a liquid to flow.
• Liquids that flow readily (water) have a low viscosity.
• Viscosity is a function of (depends on) the attractive forces of the molecules of the liquid.
• Strong forces – high viscosity
• Temperature also greatly affects viscosity: as temperature increases, viscosity decreases.
Kinetic energy enables particles to overcome forces.
Bonding & Molecular Structure• Atoms and molecules (simple and giant)
·
· State that the only substances found in atomic form are the noble gases
· Describe a molecule as a group of two or more atoms that are attracted to each other by relatively strong forces or bonds
· Give examples of molecules based on the above description e.g.
o Small molecules (relatively few atoms per molecule): oxygen, water, petrol, sugar,
o Giant molecules (millions of atoms per molecule): diamond, a sodium chloride crystal, a metal crystal like a piece of copper, …
· Recognize molecules from models (space filling, ball and stick, …)
· Draw diagrams to represent molecules using circles to represent atoms
· Represent molecules using
o Molecular formula for small molecules, e.g. O2, H2O, C8H18, C12H22O11, …
o Empirical formulae for giant molecules, e.g. C, NaCℓ, Cu,
· Give the formula of a molecule from a diagram of the molecule and vice versa
Describe the difference between inter and intra molecular forces
. · • Linking macroscopic properties of materials to micro (particle) structure