Gases, Liquids, Solids, and Intermolecular Forces PDF

Summary

This document provides a summary of properties of solids, liquids, and gases. It includes discussions on intermolecular forces, gas laws, and phase changes.

Full Transcript

Chapter 5
Gases

Chapter 11
Liquids, Solids, and
Intermolecular Forces
 Properties of the
three Phases of Matter
C A In St
om W ttr te re
p r il l ac rm n
es it tio o gth
si F l n le
bl ow s cu o f
e? ? la
State Shape Volume Density r
Solid fixed fixed high No No very strong
Liquid indefinite fixed high No Yes intermediate
Gas indefinite indefinite low Yes Yes weak

Fixed = keeps shape when placed in a container
Indefinite = takes the shape of the container
Three Phases of Water
Gas Structure

Gas molecules are
rapidly moving in random
straight lines and free from
sticking to each other.
Solids

some solids have their particles
arranged in an orderly geometric
pattern – we call these crystalline
solids
salt and diamonds
other solids have particles that
do not show a regular geometric
pattern over a long range – we call
these amorphous solids
plastic and glass
Liquids

 they have higher densities than gases
because the molecules are in close
contact

 but they have a definite volume
because the limit on their freedom
keeps them from escaping the rest of
the molecules
Phase Changes
 Gases
Gas
Gas pressure
 Explaining the Properties of Liquids

Liquids have higher densities than gases and are
incompressible because the particles are in contact

They have an indefinite shape because the limited
translational freedom of the particles allows them to
move around enough to get to the container walls

It also allows them to flow

But they have a definite volume because the limit on
their freedom keeps the particles from escaping each
other
 Surface Tension
Surface tension is a property of liquids that
results from the tendency of liquids to
minimize their surface area

To minimize their surface
area, liquids form drops
that are spherical

A trout fly can float on water
because of surface tension
 Because they have fewer
neighbors to attract them, the
surface molecules are less stable
than those in the interior

The surface tension of a liquid is
the energy required to increase
the surface area a given amount
– surface tension of H2O = 72.8 mJ/m2
at room temperature
– surface tension of C6H6 = 28 mJ/m2

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 Viscosity
Viscosity is the resistance of a liquid to flow
– 1 poise = 1 P = 1 g/cm∙s
– often given in centipoise, cP
H2O = 1 cP at room temperature
Larger intermolecular attractions = larger viscosity
 Factors Affecting Viscosity
The stronger the intermolecular attractive forces, the
higher the liquid’s viscosity will be
The more spherical the molecular shape, the lower the
viscosity will be
– molecules roll more easily
– less surface-to-surface contact lowers attractions

Raising the temperature of a liquid reduces its viscosity
– raising the temperature of the liquid increases the average kinetic
energy of the molecules
– the increased molecular motion makes it easier to overcome the
intermolecular attractions and flow
Insert Table 11.6
 Capillary Action
Capillary action is the ability of a liquid to flow
up a thin tube against the influence of gravity
– the narrower the tube, the higher the liquid rises
Capillary action is the result of two forces
working in conjunction, the cohesive and
adhesive forces
– cohesive forces hold the liquid molecules together
– adhesive forces attract the outer liquid molecules to
the tube’s surface
 Capillary Action
The adhesive forces pull the surface liquid up the side
of the tube, and the cohesive forces pull the interior
liquid with it
The liquid rises up the tube until the force of gravity
counteracts the capillary action forces
The narrower the tube diameter, the higher the liquid
will rise up the tube
 Meniscus
The curving of the liquid surface in a
thin tube is due to the competition
between adhesive and cohesive forces

The meniscus of water is concave in a
glass tube because its adhesion to the
glass is stronger than its cohesion for
itself

The meniscus of mercury is convex in
a glass tube because its cohesion for
itself is stronger than its adhesion for
the glass
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 Vaporization
If these high energy molecules
are at the surface, they may
have enough energy to
overcome the attractive forces
– therefore – the larger the
surface area, the faster the
rate of evaporation
This will allow them to escape
the liquid and become a vapor
 Condensation
Some molecules of the vapor will lose
energy through molecular collisions
The result will be that some of the
molecules will get captured back into the
liquid when they collide with it
Also some may stick and gather together to
form droplets of liquid
– particularly on surrounding surfaces
We call this process condensation
 Boiling Point
When the temperature of a liquid reaches a
point where its vapor pressure is the same as
the external pressure, vapor bubbles can form
anywhere in the liquid
– not just on the surface
This phenomenon is what is called boiling and
the temperature at which the vapor pressure =
external pressure is the boiling point
 Boiling Point
The normal boiling point is the temperature at
which the vapor pressure of the liquid = 1 atm
The lower the external pressure, the lower the
boiling point of the liquid
 Sublimation and Deposition
Molecules in the solid have thermal energy that
allows them to vibrate
Surface molecules with sufficient energy may
break free from the surface and become a gas –
this process is called sublimation
The capturing of vapor molecules into a solid is
called deposition
The solid and vapor phases exist in dynamic
equilibrium in a closed container
– at temperatures below the melting point
– therefore, molecular solids have a vapor pressure
sublimation
solid deposition gas
Sublimation