Calorimetry
Lesson 1 of this chapter focused on the meaning of
temperature and heat. Emphasis was given to the development of a particle model
of matter that is capable of explaining the macroscopic observations. Efforts
have been made to develop solid conceptual understandings of the topic in the
absence of mathematical formulas. We learned that heat flows from one object to
another (between the system and the surroundings) when a temperature difference exists between system and surroundings.
Now in this unit we will investigate the topic of measuring the quantity of
heat that is transferred between the system and the surroundings. This lesson
is devoted to calorimetry - the science associated with determining the changes
in energy of a system by measuring the heat exchanged with the surroundings.
Before we can understand the mathematics of calorimetry, we should answer a
critical question that was at least in part addressed in Lesson 1. The question is: what does heat do? When heat is lost or gained by an
object, what does it do?
For some students, the very question what does
heat do? is confusing.
Think about the question a moment. Does the question (not just the answer)
confuse you? Confusion over the question is sometimes caused by misconceptions
about what heat is. The reason for the lengthy discussions in Lesson 1 was to
provide a solid conceptual foundation for understanding the mathematics of
Lesson 2. If the question is confusing, you might want to review Lesson 1 or at
least review the discussion pertaining to What is Heat? In Lesson 1, it was emphasized that heat is not something that is contained in an
object. Objects do not contain heat. Objects,
which are made of atoms, molecules and ions, contain energy. Heat is the
transfer of energy from an object to its surroundings or to an object from its
surroundings. So the question being asked on this page is what does this heat
do to the object and to the surroundings when it is transferred? Like many
questions in physics, it is a simple answer with deep meaning. Simple answers
with deep meaning always exercise the brain. So put on your thinking cap and
let's get to the answer.
What does heat do? First, it changes the temperature of an
object. If heat is transferred from an object to the surroundings, then the
object can cool down and the surroundings can warm up. When heat is transferred
to an object by its surroundings, then the object can warm up and the
surroundings can cool down. Heat, once absorbed as energy, contributes to the
overall internal energy of the object. One form of this internal energy is
kinetic energy; the particles begin to move faster, resulting in a greater
kinetic energy. This more vigorous motion of particles is reflected by a temperature
increase. The reverse logic applies as well. Energy, once released as heat,
results in a decrease in the overall internal energy of the object. Since
kinetic energy is one of the forms of internal energy, the release of heat from
an object causes a decrease in the average kinetic energy of its particles.
This means that the particles move more sluggishly and the temperature of the
object decreases. The release or absorption of energy in the form heat by an
object is often associated with a temperature change of that object. This was
the focus of the Thermometers as Speedometers in Lesson 1. What can be said of the object can also be said of the surroundings.
The release or absorption of energy in the form heat by the surroundings is
often associated with a temperature change of the surroundings. We often find
that the transfer of heat causes a temperature change in both system and
surroundings. One warms up and the other cools down.
But does the absorption or release of energy in the form of
heat always cause a temperature change? Surprisingly, the answer is no. To
illustrate why, consider the following situation, which is often demonstrated
or even experimented with in a thermal physics unit in school.
Para-dichlorobenzene, the main ingredient in many forms of mothballs, has a
melting point of about 54 °C. Suppose that a sample of the chemical is
collected in a test tube and heated to about 80°C. The para-dichlorobenzene
will be in the liquid state (though much of it will have sublimed and be
filling the room with a most noticeable aroma). Now suppose that a thermometer
is inserted in the test tube and that the test tube is placed in a beaker of
room temperature water. Temperature-time data can be collected every 10
seconds. Quite expectedly, one notices that the temperature of the
para-dichlorobenzene gradually decreases. As heat is transferred from the high
temperature test tube to the low temperature water, the temperature of the
liquid para-dichlorbenzene decreases. But then
quite unexpectedly, one would notice that this steady decrease in temperature
ceases at about 54°C. Once the temperature of liquid para-dichlorbenzene decreases
to 54°C, the thermometer level suddenly stands
still. Based on the thermometer reading, you might
think that no heat was being transferred. But a look in the test tube reveals
dramatic change taking place. The liquid para-dichlorbenzene is
crystallizing to form solid para-dichlorbenzene. Once
the last trace of liquid para-dichlorbenzene vanishes
(and it is in all solid form), the temperature begins to decrease again from
54°C to the temperature of the water. How can these observations help us to
understand the question of what does heat do?
First, the decrease in temperature from 80°C to 54°C is easy
to explain. We have learned in Lesson 1 that heat is transferred between two adjacent
objects that are at different temperatures. The test tube and the para-dichlorbenzene are at a higher temperature than the
surrounding water of the beaker. Heat will flow from the test tube of para-dichlorbenzene to the water, causing the para-dichlorbenzene to cool down and the water to warm up.
And the decrease in temperature from 54°C to the temperature of the water in
the beaker is also easily explainable. Two adjacent objects of different
temperatures will transfer heat between them until thermal equilibrium is
reached. The difficult explanation involves explaining what happens at 54°C.
Why does the temperature no longer decrease when the liquid para-dichlorbenzene begins to crystallize? Is there still a
transfer of heat between the test tube of para-dichlorbenzene and
the beaker of water even when the temperature isn't changing?
The answer to the question Is heat being transferred? is a resounding yes! After all, the
principle is that heat is always transferred between two adjacent objects that
are at different temperatures. A thermometer placed in the water reveals that
the water is still warming up even though there is no temperature change in the
para-dichlorbenzene. So heat is definitely being
transferred from the para-dichlorbenzene to the
water. But why does the temperature of the para-dichlorbenzene remain
constant during this crystallization period? Before the para-dichlorbenzene can continue to lower its temperature,
it must first transition from the liquid state to the solid state. The
crystallization of para-dichlorbenzene occurs at
54°C - the freezing point of the substance. At this temperature, the energy
that is lost by the para-dichlorbenzene is
associated with a change in the other form of internal energy - potential
energy. A substance not only possesses kinetic energy due to the motion of its
particles, it also possesses potential energy due to the intermolecular
attractions between particles. As the para-dichlorbenzene crystallizes
at 54°C, the energy being lost is reflected by decreases in the potential
energy of the para-dichlorbenzene as it changes
state. Once all the para-dichlorbenzene has
changed to the solid state, the loss of energy is once more reflected by a
decrease in the kinetic energy of the substance; its temperature decreases.
So the second answer to the question What does heat do? is that it contributes to changes in state
of a substance. Most students are familiar with at least three states of matter
- solid, liquid and gas. The addition of heat to a sample of matter can cause
solids to turn to liquids and liquids to turn to gases. Similarly, the removal
of heat from a sample of matter can cause gases to turn to liquids and liquids
to turn to solids. Each of these transitions between states occur at specific
temperatures - commonly referred to as melting point temperature, freezing point
temperature, boiling point temperature and condensation point temperature.
To further illustrate this relationship between heat
transfer, temperature change and change of state, consider the following thought
experiment. Suppose that a sample of water was placed in
a Styrofoam cup with a digital thermometer. And suppose that the water is
placed in the freezer (temperature = -20°C) and frozen. Suppose that the
thermometer can be connected to a computer with software that is capable of
collecting temperature-time data. After the water has frozen and remained in
the freezer for several hours, it is removed and placed in a beaker on a hot plate. The hot plate is turned on, gets hot, and begins transferring energy
in the form of heat to the beaker and the water. What changes would be observed
in the temperature and the state of matter of the water over the course of time?
The diagram below depicts the so-called heating curve for the
water. The heating curve represents the changes in temperature with respect to time
for a sample of matter (such as the water) to which heat is transferred.
Observe that there are three sloped sections and two
horizontal sections on the temperature-time plot. The first sloped section
corresponds to a change in temperature of the ice from -20°C to 0°C. The water
in its solid state is warming up to the melting point - the temperature at
which water transitions between the solid and the liquid state. The heat
transferred to the ice causes a temperature change. Once the transition
temperature (melting point) of 0°C is reached, the heat added to the water
causes the water to change from its solid state to its liquid state. This is
referred to as melting. The melting occurs at a constant temperature. During
this stage of the experiment, the
energy absorbed by the water is used to loosen the attractions that hold one
ice particle to another. Once all these attractions are loosened, the ice would
be observed to have entirely melted. The contents of the Styrofoam cup are
completely liquid. The next section of the heating
curve is a sloped section. The liquid water is increasing its temperature from 0°C to 100°C. The boiling point
of water is 100°C; this is the temperature at which water transitions from the
liquid state to the gaseous state. Once the sample of water reaches this
temperature, boiling occurs. Large bubbles of gas would be observed forming
throughout the bulk of the liquid. The heat added to the liquid during this
stage of the thought experiment causes a loosening of the attractions that hold
the water particles in the liquid state. The temperature remains constant while
the state of water changes. Once all the water transitions from the liquid to
the gaseous state, the sample of water (now in the gaseous state) begins to increase
its temperature again.
In summary, the three sloped sections represent heat causing
a temperature change in the substance that absorbs it. And the two plateau
sections represent heat causing a change of state in the substance that absorbs
it. An inquisitive student might ask, "What is the particle-level
explanation of these changes?" (Thanks for asking.) The temperature
changes are the result of the added energy causing the particles of water to
move more vigorously. Either the particles of solid vibrate more vigorously
about their fixed positions or the particles of liquid and gas move about their
container more rapidly. Either way, the addition of heat is causing an increase
in the average kinetic energy of the particles in the sample of water. The changes
of state are the result of the added energy causing changes in the strength of
the inter-particle attractions. The attractions that hold water in the solid or
in the liquid state are being overcome. The energy is being used to loosen
these attractions and change to a state of greater potential energy.
(a) Water in a flask is heated to is boiling point. The gas
exiting the flask cools while passing through the copper tubing. Condensed
water droplets are seen exiting the end of the copper tube.
(b) The temperature of this condensed water is much
less than 100°C. It is not hot enough to cause a burn.
(c) A bunsen burner flame is used to heat the condenser coils of the
copper tube. This raises the temperature of the exiting water above the boiling
point. It's gaseous water above 100°C that is exiting the copper tubing.
(d) This water vapor is so hot that it instantly ignites a match that is
placed at its opening.
(e) Still being heated by the bunsen burner flame, the
exiting water vapor is hot enough to scorch a sheet of paper ...
(f) ... and that spells phun for the people doing and watching the demonstration!
So the transfer of energy in the form of heat is associated
with changes in the temperature or changes in the state of a sample of matter.
But is that all? Can heat do anything else? Once more, the answer is Yes! Energy transfer in the form of heat can result in the
performance of work upon the system or the surroundings. Devices that utilize
heat to do work are often referred to as heat engines. In general, an engine is a
device that does work. A heat engine is a device that uses heat transfer as the
source of energy for doing work.
The internal combustion engine of an automobile is an example
of a heat engine. Most internal combustion engines use a four-cycle process
that is depicted in the animation at the right. As the fuel is burned (reacted
with oxygen) in the engine, energy is released from the system of chemicals.
There is a heat transfer from the hot system to the surrounding air of the
cylinder. This transfer of heat to the air in the cylinder does work upon the
piston, driving it downward. The piston is connected to the crankshaft of the
car. The back and forth movement of the piston within the cylinder results in
the rotational motion of the crankshaft and the generation of the energy
required to set the car in motion. The internal combustion engine is an example
of a heat engine. In this case, the internal energy stored in the chemical
(gasoline) is converted to thermal energy (the flow of heat) that results in
the performance of work. Heat engines will be discussed in greater detail in
the Thermodynamics chapter of The Physics Classroom Tutorial. (Special thanks
to UtzOnBike and theWikiMedia Commons for the
animation of the four-cycle Otto engine as used above.)
Heat is the flow of energy from a high temperature location
to a low temperature location. This flow of energy is always associated with
changes in the system and the surroundings. There can be changes in the
temperature, changes in the state of matter and changes that result from the
doing of work. In the next section, we will
look at the science of calorimetry. We will find that there is a very
predictable set of mathematics associated with these changes. In fact, they are
so predictable that scientists can use them to measure the amount of energy
flow.