Chapter 11 Lecture 1 and 2 Liquids, Solids, and Intermolecular Forces PDF

Summary

This lecture discusses the properties of liquids, solids, and gases, focusing on intermolecular forces and their effect on the states of matter. Topics include dispersion forces, dipole-dipole interactions, and hydrogen bonding.

Full Transcript

Chapter 11 Lecture 1 and 2
Liquids, Solids, and Intermolecular
Forces
 Phases of Matter

https://myarkansaspbs.pbslearningmedia.org/resource/phases-of-matter-the-3-phases-animation/unc-tv-science/
Properties of the States of Matter:
Solids
High densities compared to gases.
Nonfluid.
They move as an entire “block” rather than a smooth, continuous
flow.
Keep their own shape, do not take the shape of their
container(s).
Keep their own volume, do not expand to fill their
container(s).
Cannot be compressed into a smaller volume.

3
Properties of the States of Matter:
Liquids
High densities compared to gases.
Fluid.
The material exhibits a smooth, continuous flow as it moves.
Take the shape of their container(s).
Keep their volume, do not expand to fill their container(s).
Cannot be compressed into a smaller volume.

4
Properties of the States of Matter:
Gases
Low densities compared to solids and liquids.
Fluid.
The material exhibits a smooth, continuous flow as it moves.
Take the shape of their container(s).
Expand to fill their container(s).
Can be compressed into a smaller volume.

5
The state which occurs will depend on two
things:

1. The kinetic energy in the particles
(proportional to temperature)
2. The strength of the forces binding the
particles together.
Changes Between States
Example of Change Between States

Liquefied petroleum (LP) gas used
as a fuel for outdoor grills and lanterns.
Gas at room temperature and
atmospheric pressure.
Liquid at 2.7 atm.
Intramolecular vs Intermolecular Forces

Intramolecular forces are interactions of
atoms within a molecule.
Intermolecular forces are interactions
between molecules.
Among other things, intermolecular forces are
responsible for condensation of gases, and
freezing of liquids into solids.

Intermolecular Forces
Attractive Forces

Intermolecular forces (IMF): electrostatic

Strength varies, dependent on structure and charge.

The stronger the attractive forces between the particles, the
more they resist moving
though no material completely lacks particle motion
Intermolecular Forces
(also called non-covalent interactions)

Attractive forces between molecules and ions.
Determine bulk properties of matter.
Much weaker than chemical bonds. (10’s of kJ/mol vs. 100’s
of kJ/mol)
(this is why boiling water doesn’t make hydrogen and
oxygen, just make steam.)
Think of as the “stickiness” of the particles
Several types, dependent on structure and charge distribution.
 Coulomb’s Law
1  q1q2  the potential energy (E) of two oppositely charged particles (with
E  
charges q1 and q2) decreases (becomes more negative) with
increasing magnitude of charge and with decreasing separation
k r  (r). k is constant equal to 4πϵ˚.

But we know that molecules can have partial charges if they have polar
bonds.

The interactions between these partial charges are the basis of
intermolecular forces.

δ- δ+ δ- δ+

Intermolecular Forces
 1  q1q2 
E  
k r 
What does this tell you about the strength of intermolecular
forces compared to bonding forces ?

Intermolecular forces also act over
much larger distances compared to
electron-proton interactions.
Intermolecular Forces
Several types of forces:
Dispersion
instantaneous induced dipole
all molecules/atoms/ions experience this interaction

Strength
depends on polarizability of particle
Dipole-Dipole
molecule must have a permanent dipole
depends on dipole moment
Hydrogen Bonding
must be a polar molecule
H covalently-bound to F, N, or O
Ion-Dipole
Interactions between ions and polar molecules
Dispersion Forces

Attraction is due to instantaneous, temporary dipoles formed
due to electron motions.

Temporary partial charges
Instantaneous Dipoles

17
All molecules, regardless of structure,
experience dispersion forces. These include
nonpolar molecules.

-Now suppose that one of the molecules has, for a
split second, an unsymmetrical distribution of
charge.
-The existence of this temporary dipole induces
dipole moments in adjacent molecule.
The magnitude of the dispersion force
depends on the polarizability and shape of
the atom or molecule.
 volume of the electron cloud
 larger molar mass = more electrons = larger
electron cloud = increased polarizability =
stronger attractions
 more surface-to-surface contact = larger
induced dipole = stronger attraction
Effect of Molar Mass on Boiling Points
Effect of Molecular Shape
on Size of Dispersion Force
the larger surface-to-
surface contact
between molecules
in n-pentane results
in stronger
dispersion force
attractions
Practice – Choose the Substance in Each Pair with the Higher
Boiling Point
a- Both
a) CH4 C4H10 molecules
are nonpolar
larger molar
mass
b) C6H12 C6H12
b- Both molecules
are nonpolar, but the
flatter ring molecule
has larger surface-
to-surface contact
Dipole–Dipole Attractions
Polar molecules have a permanent dipole
because of bond polarity and shape
dipole moment
as well as the always present induced dipole
The permanent dipole adds to the attractive forces between
the molecules
raising the boiling and melting points relative to nonpolar
molecules of similar size and shape
Molecular Polarity
 Dipole-Dipole
Attractions

Strength of the interaction
depends on the magnitude of
the dipole.
Indicates similar polarizabilities,
therefore similar dispersion effects.
Practice – Choose the substance in each pair
with the higher boiling point

a) CH2FCH2F CH3CHF2
or

b)
or
Practice – Choose the substance in each pair with
the higher boiling point

a) CH2FCH2F CH3CHF2 more polar

b)
or
polar nonpolar
Hydrogen-Bonding
Molecules containing N–H, O–H, or F–H
groups, and an electronegative O, N, or F.
Not really a chemical bond!

Can vary from ~10 to ~100 kJ/mol.
H-Bonding in Water
Hydrogen bonding DNA
Double Stranded DNA
Practice – Choose the substance in each pair that is a liquid at room
temperature (the other is a gas)

a) CH3OH CH3CHF2
can H-bond

b) CH3-O-CH2CH3 CH3CH2CH2NH2
can H-bond
 Ion–Dipole Attraction
In a mixture, ions from an ionic compound are attracted to the
dipole of polar molecules
The strength of the ion–dipole attraction is one of the main
factors that determines the solubility of ionic compounds in
water
 IMF and Solubility
Solubility depends, in part, on IMF
like dissolves like
Polar substances dissolve in polar solvents
hydrophilic groups = OH, CHO, C=O, COOH, NH2, Cl
HO
H OH H O
O
H N H HO
H C C H C O
H
H O H H
HO OH
Acetic Acid Ammonia Methanol Ascorbic Acid (Vit. C)

Nonpolar molecules dissolve in nonpolar solvents; Hexane, Pentane
hydrophobic groups = C-H, C-C
Immiscible Liquids
Pentane, C5H12 is a nonpolar
molecule.

Water is a polar molecule.

The attractive forces between
the water molecules is much
stronger than their attractions for
the pentane molecules. The
result is the liquids are
immiscible.
Polar Solvents

Ethanol
(ethyl alcohol)

Dichloromethane Water
(methylene chloride)
Nonpolar Solvents
Practice – Choose the substance in each pair that is more
soluble in water

a) CH3OH CH3CF2
H
can H-bond with H2O

more polar
b) CH3CH2CH2CH2CH3 CH3Cl