Chemistry 101: Intermolecular Forces of Attraction PDF

Summary

This document provides a detailed overview of intermolecular forces in chemistry. It explores the kinetic molecular theory, various types of intermolecular forces (including dipole-dipole, dispersion), and their effects on liquid properties, such as surface tension, viscosity, and boiling point. The text also includes diagrams and illustrations to visually support the explanation.

Full Transcript

C H E M I S T R Y 1 0 1
Have you ever
wondered why there
are droplets of water
on the outer side
of a cold glass?
GENERAL
CHEMISTRY
CLASS 2
CHAPTER 1 Intermolecular Forces in Liquids and Solids
1. Kinetic molecular model of liquids and solids
2. Intermolecular Forces
Dipole-dipole forces
Ion-dipole forces
Dispersion forces
Hydrogen bonds
3. Properties of liquids and IMF
Surface Tension
Viscosity
Vapor pressure
boiling point
Molar heat of vaporization
4. Structure and Properties of Water
Objectives
At the end of the lesson students are able to;
1. explain the kinetic molecular model of solids and liquids,
2. differentiate the characteristic of solids and liquids,
3. analyse the intermolecular forces of attraction exist
between particles of substances, and
4. appreciate the chemistry of things around us.
Concepts in a Box

Kinetic Molecular Model

Explain the
properties of

Liquids Solids

can be
Have particles held
classified as
together by
Surface Tension
Viscosity
Vapor pressure Intermolecular Forces Amorphous Crystalline
Boiling point Dipole-dipole forces Ionic
Heat of Ion-dipole forces Molecular
vaporization Dispersion forces Metallic
Hydrogen bonds Network
Group 8A
LESSON 1:
The Kinetic Molecular Models of liquids and solids
Intermolecular Forces of Attraction in Matter
 Less closely
Arrangement Closely packed packed than in Very far apart
of Particles orderly disorderly
Kinetic Molecular Theory

solid
disorderly
Particles
Kinetic Energy Particles move
vibrate and Particles slide
of Particles about at great
rotate about over each other
speed
fixed position

Particle Motion Very low low High

Attractive forces
between Very strong strong Very weak
particles
Dipole-dipole forces
Ion-dipole forces
Intermolecular Dispersion forces
forces
Hydrogen bonds
Kinetic Molecular Theory
Kinetic- Kinetos (Greek word) which means “Movable”

It explains the properties of solids, liquids, and gas in terms
of intermolecular forces of attraction and the kinetic energy
of the individual particles.
What do you
observe?
 Intermolecular forces < kinetic energy of molecules

Intermolecular forces > kinetic energy of molecules
 Properties

Have definite Shape Have no definite Shape
Do not flow Flow and take the shape of
Virtually incompressible their container
Expand when heated, but Very difficult to compress
to a lesser extent than Slightly expand when
liquids and gases. heated.
 Particles

Strongly attracted to each Weakly attracted to each
other other; break their
Vibrate a little, but not interaction easily
much compared to liquids Vibrate and move more
and gases than those in a solid
Vibrate faster when Move faster when heated
heated
Intermolecular Forces of Attraction
Strong intramolecular
attraction (Covalent bond)

This force holds the molecules together
which can be attractive or repulsive.

Weak intermolecular
attraction

The attractions between molecules are not nearly as strong as the
intramolecular attractions (bonds) that hold compounds together.
Many physical properties reflect intermolecular forces, like boiling
points, melting points, viscosity, surface tension, and capillary
action.
Types of Intermolecular Force
Weakest to strongest forces:
dispersion forces (or London dispersion forces)
dipole–dipole forces
hydrogen bonding (a special dipole–dipole force)
ion–dipole forces

Note: The first two types are also referred to collectively as
van der Waals forces.
Dipole–Dipole Interactions
Polar molecules have a more positive and a more
negative end–a dipole (two poles, δ+ and δ−).
The oppositely charged ends attract each other.

Strong intramolecular
attraction (Covalent bond)

Weak intermolecular
attraction
For molecules of approximately equal mass and size, the
more polar the molecule, the higher its boiling point.
Hydrogen Bonding
The dipole–dipole interactions
experienced when H is bonded to
N, O, or F are unusually strong.
A hydrogen bond is an attraction
between a hydrogen atom
attached to a highly
electronegative atom and a
nearby small electronegative
atom in another molecule or
chemical group.
What Forms Hydrogen Bonds?
Hydrogen bonding arises in part from the high
electronegativity of nitrogen, oxygen, and fluorine.
These atoms interact with a nearly bare nucleus (which
contains one proton).
 Hydrogen bonding in ammonia
contains highly electronegative
atom nitrogen linked to
hydrogen atoms

Hydrogen bonding in Fluoride
Fluorine, having the highest value
of electronegativity forms the
strongest hydrogen bond.

Hydrogen Bonding in Water
A water molecule contains a highly electronegative
oxygen atom linked to the hydrogen atom. Oxygen
atom attracts the shared pair of electrons more and
this end of the molecule becomes negative whereas
the hydrogen atoms become positive.
Ion–Dipole Interactions
Ion–dipole interactions are found in solutions of ions.
The strength of these forces is what makes it possible for
ionic substances to dissolve in polar solvents.

Mg⁺
----
K⁺
Dispersion Forces
The figure below shows how a nonpolar particle
(in this case a helium atom) can be temporarily polarized
to allow dispersion force to form.
The tendency of an electron cloud to distort is 0 – 0.5 EN
called its polarizability.
Summarizing Intermolecular Forces
Factors Which Affect Amount of
Dispersion Force in a Molecule
number of electrons
in an atom (more
electrons, more
dispersion force)
size of atom or
molecule/molecular
weight
shape of molecules
with similar masses
(more compact, less
dispersion force)
Polarizability & Boiling Point
If something is easier to
polarize, it has a lower
boiling point.
Remember: This means less
intermolecular force
(smaller molecule: lower
molecular weight, fewer
electrons).
LESSON 2:
Intermolecular Forces and Properties of Liquid
Liquid Properties Affected by Intermolecular
Forces
boiling point
viscosity
surface tension
Heat of vaporization
capillary action
Cohesion and Adhesion
Intermolecular forces that bind similar molecules
to one another are called cohesive forces.
Intermolecular forces that bind a substance to a
surface are called adhesive forces.
These forces are important in capillary action.
 Capillary Action
The rise of liquids up narrow
tubes is called capillary
action.
Cohesive forces attract
the liquid to itself.
Adhesive forces attract
the liquid to the wall of
the tube.
Water has stronger adhesive
forces with glass; mercury has
stronger cohesive forces with
itself.
Surface Tension
Water acts as if it has a
“skin” on it due to
extra inward forces on
its surface. Those
forces are called the
surface tension.
Arrange the following from quickly flowing liquid to liquid that
moves more slowly:
 Viscosity
Resistance of a liquid to flow is called
viscosity.
It is related to the ease with which molecules
can move past each other.
Viscosity increases with stronger
intermolecular forces and decreases with
higher temperature.
 Boiling
When a liquid is heated
to a temperature when
all molecules have
enough kinetic energy
to vaporize, the liquid
begins to boil.
Boiling happens
at a boiling point,
Vapor forms within
the liquid.
What is in the bubble?
Boiling
At the boiling
point, bubbles
of vapor form
within the
liquid.
The pressure
within the
bubble is due to
the vapor
pressure.

When vapor pressure in the bubble equals external pressure,
the bubble rises to the surface of the liquid and bursts.
 Vapor Pressure
Vapor pressure is a
pressure of vapor
particles exerted on the
walls of a container.
An increase in the
temperature of a liquid
increases the vapor
pressure.
Analyze the diagram
Boiling Point (temp. of boiling)
The boiling point is the temperature at which the
vapor pressure of a liquid is equal to the external
pressure.
 Normal Boiling Point
Normal boiling point is a boiling point when the
external/atmospheric pressure is 1 atm.
Vapor Pressure vs. Temperature
Boiling Point
Summary
Boiling Point
depends on
Strength of
intermolecular
forces in a
substance
External/atmos
pheric pressure
Boiling: analyze the process from
the point of IMF
Liquids have quite strong IMFs
Gasses have no IMFs
Particles of liquid should break IMFs to move
from the liquid phase to the gas phase.
Energy is required to break IMFs.
Boiling
Boiling is a process that takes time and energy.
Why do we need to supply energy all the time to support
boiling? Try to think about the process considering kinetic
energies of particles in a liquid.
When particles with higher kinetic energy leave the liquid

the temperature of the liquid decreases,

constant supply of energy is needed to break IMFs and
support boiling temperature.

Boiling is an endothermic process.
Vaporization
 Vapor Pressure
At any temperature, some
liquid molecules have
enough energy to escape
the surface and become a
gas.
As the temperature rises,
the fraction of molecules
that have enough energy to
break free increases.
Vapor Pressure
As more molecules
escape the liquid, the
pressure they exert
increases.
The liquid and vapor
reach a state of
dynamic equilibrium:
liquid molecules
evaporate and vapor
molecules condense at
the same rate.
Vapor Pressure
The boiling point of a
liquid is the temperature
at which its vapor
pressure equals
atmospheric pressure.
The normal boiling point
is the temperature at
which its vapor pressure
is 760 torr.
Vapor Pressure
The natural log of the vapor
pressure of a liquid is
inversely proportional to its
temperature.
This relationship is quantified
in the Clausius–Clapeyron
equation.