Specific heat capacity
Temperature
and heat are not the same thing:
- temperature is a measure of how
hot something is
- heat is a measure of the
thermal energy contained in an object.
Temperature
is measured in °C, and heat is measured in J. When heat energy is transferred
to an object, its temperature increase depends upon the:
- the mass of the object
- the substance the object is
made from
- the amount energy transferred
to the object.
For a
particular object, the more heat energy transferred to it, the greater its
temperature increase.
Specific heat capacity
The specific
heat capacity of a substance is the amount of energy needed to change the
temperature of 1 kg of the substance by 1°C. Different substances have
different specific heat capacities. The table shows some examples.
Heat capacities of different substances
|
Substance
|
Specific heat capacity in J / kg °C
|
|
water
|
4181
|
|
oxygen
|
918
|
|
lead
|
128
|
Notice that
water has a particularly high specific heat capacity. This makes water useful
for storing heat energy, and for transporting it around the home using central
heating pipes.
Calculating specific heat capacity
Here is the
equation relating energy to specific heat capacity:
E = m × c ×
θ
- E is the energy transferred in
joules, J
- m is the mass of the substances
in kg
- c is the specific heat capacity
in J / kg °C
- θ (‘theta’) is the temperature
change in degrees Celsius, °C
For example,
how much energy must be transferred to raise the temperature of 2 kg of water
from 20°C to 30°C?
E = m × c ×
θ (θ = 30 – 20 = 10°C)
E = 2 × 4181
× 10 = 83,620 J or 83.62 kJ
|
Specific Heat and Heat Capacity
|
Specific
heat is another physical property of matter. All matter has a temperature
associated with it. The temperature of matter is a direct measure of the motion
of the molecules: The greater the motion the higher the temperature:
Motion
requires energy: The more energy matter has the higher temperature it will also
have. Typicall this energy is supplied by heat. Heat loss or gain by matter is
equivalent energy loss or gain.
With the
observation above understood we con now ask the following question: by how much
will the temperature of an object increase or decrease by the gain or loss of
heat energy? The answer is given by the specific heat (S) of the object. The specific
heat of an object is defined in the following way: Take an object of mass m,
put in x amount of heat and carefully note the temperature rise, then S is
given by
In this
definition mass is usually in either grams or kilograms and temperatture is either
in kelvin or degres Celcius. Note that the specific heat is "per unit
mass". Thus, the specific heat of a gallon of milk is equal to the
specific heat of a quart of milk. A related quantity is called the heat
capacity (C). of an object. The relation between S and C is C = (mass of obect)
x (specific heat of object). A table of some common specific heats and heat
capacities is given below:
|
Some
common specific heats and heat capacities:
|
|
Substance
|
S (J/g 0C)
|
C (J/0C) for 100 g
|
|
Air
|
1.01
|
101
|
|
Aluminum
|
0.902
|
90.2
|
|
Copper
|
0.385
|
38.5
|
|
Gold
|
0.129
|
12.9
|
|
Iron
|
0.450
|
45.0
|
|
Mercury
|
0.140
|
14.0
|
|
NaCl
|
0.864
|
86.4
|
|
Ice
|
2..03
|
203
|
|
Water
|
4.179
|
41.79
|
|
|
|
|
Consider the
specific heat of copper , 0.385 J/g 0C. What this means is that it takes 0.385
Joules of heat to raise 1 gram of copper 1 degree celcius. Thus, if we take 1
gram of copper at 25 0C and add 1 Joule of heat to it, we will find that the
temperature of the copper will have risen to 26 0C. We can then ask: How much
heat wil it take to raise by 1 0C 2g of copper?. Clearly the answer is 0.385 J
for each gram or 2x0.385 J = 0.770 J. What about a pound of copper? A simple
way of dealing with different masses of matter is to dtermine the heat capacity
C as defined above. Note that C depends upon the size of the object as opposed
to S that does not.
We are not
in position to do some calculations with S and C.
Example 1: How much energy does it take to
raise the temperature of 50 g of copper by 10 0C?
Example 2: If we add 30 J of heat to 10 g of
aluminum, by how much will its temperature increase?
Thus, if the
initial temperture of the aluminum was 20 0C then after the heat is added the
temperature will be 28.3 0C.
Specific Heat Capacity
The specific heat capacity of a solid or liquid is defined
as the heat required to raise unit mass of substance by one degree of
temperature. This can be stated by the following equation:
where,
Q= Heat supplied to
substance,
m= Mass of the substance,
c= Specific heat capacity,
T= Temperature rise.
There are two definitions for vapors and gases:
Cp = Specific heat capacity at constant pressure, i.e.
Cv = Specific heat capacity at constant volume, i.e.
It can be shown that for a
perfect gas:
where R is the gas constant. The ratio, Cp/Cv, has been given symbol
,
and is always greater than unity. The approximate value of this ratio is 1.6
for monatomic gases such as Ar and He. Diatomic gases (such as H2, N2, CO and
O2) have a g ratio about 1.4 and triatomics (such as SO2 and CO2) 1.3.
Specific Heat Capacity Table
|
Substance
|
Specific Heat Capacity
at 25oC in J/goC
|
|
H2 gas
|
14.267
|
|
He gas
|
5.300
|
|
H2O(l)
|
4.184
|
|
lithium
|
3.56
|
|
ethyl alcohol
|
2.460
|
|
ethylene glycol
|
2.200
|
|
ice @ 0oC
|
2.010
|
|
steam @ 100oC
|
2.010
|
|
vegetable oil
|
2.000
|
|
sodium
|
1.23
|
|
air
|
1.020
|
|
magnesium
|
1.020
|
|
aluminum
|
0.900
|
|
Concrete
|
0.880
|
|
glass
|
0.840
|
|
potassium
|
0.75
|
|
sulphur
|
0.73
|
|
calcium
|
0.650
|
|
iron
|
0.444
|
|
nickel
|
0.440
|
|
zinc
|
0.39
|
|
copper
|
0.385
|
|
brass
|
0.380
|
|
sand
|
0.290
|
|
silver
|
0.240
|
|
tin
|
0.21
|
|
lead
|
0.160
|
|
mercury
|
0.14
|
|
gold
|
0.129
|
Heat energy
The jam in a sponge pudding stays hotter for
longer than the pudding around it
Water is a very good coolant for use in engines
Saucepans are made of materials with a low mass if possible
It takes a long time to heat up enough water to have a hot bath
Houses built with thick stone walls keep warm in winter and stay cool in summer
People used to warm up heavy china teapots before putting the hot water and tea
in them
Storage radiators are used to retain heat energy for use later in the day
You can put out a candle flame (temperature 800 oC) with moist
fingers without pain but putting your hand into a bowl of boiling water (100 oC)
would hurt a lot!
Electronic circuits are built with "heat sinks"
When you run "hot" water into a basin it cools as soon as it touches
the material of the basin
Liquid sodium is used as a coolant in some nuclear reactors
All these facts are related to heat energy and to a quantity known as
specific heat capacity and we can explain them by looking more closely at heat
energy.
Over the past few centuries scientists have put forward some very strange
theories about the nature of heat. One of these was that heat was some sort of
a fluid that you added to a body to make it hot and took away from a body to
cool it down.
However, during the last century two men, Rumford and Joule, both proposed the
idea that heat was related to energy. When heat energy passes into a body it
increases the internal energy of the body. Rumford demonstrated this in some
well-known experiments in cannon boring and Joule showed that the friction
generated between a paddle wheel and some water would heat up the water.
We can summarise these results
as:
To heat up a substance requires energy.
This energy increases the internal energy of the substance by increasing the
kinetic energy of its molecules and so the temperature of the substance rises
Heat capacity and specific heat capacity
The amount of heat energy needed
to change the temperature of a substance depends on:
(a) what the substance is;
(b) how much of it is being heated;
(c) what rise in temperature occurs.
The heat energy needed to raise the temperature of an object by 1 K is called
the HEAT CAPACITY of the object.
However, a rather more useful quantity is the heat energy needed for 1 kg only.
The SPECIFIC HEAT CAPACITY of a
substance is the heat needed to raise the temperature of 1 kg of the substance
by 1K (or by 1oC).
Specific heat capacity is given the symbol c. The units for c are J/(kg K) or
J/(kgoC).
The values for the specific heat capacities of some common substances are given
in the following table:
|
Substance
|
Specific heat capacity (J/(kgK)
|
Substance
|
Specific heat capacity (J/(kgK)
|
|
Water
|
4200
|
Aluminium
|
913
|
|
Cast iron
|
500
|
Brick
|
2300
|
|
Copper
|
385
|
Concrete
|
3350
|
|
Lead
|
126
|
Marble
|
880
|
Remember that substances with high specific heat capacities take a lot of
heat energy and therefore a long time to heat up and also a long time to cool down.
One interesting effect is the way in which the land heats up quicker than the
sea - the specific heat capacity of sea water is greater than that of the land
and so more heat energy is needed to heat it up by the same amount as the land
and so it takes longer. It also takes longer to cool down.
The heat energy needed to raise the temperature of m kg of a substance of
specific heat capacity c by a certain temperature difference is given by the
equation:
Heat energy = mass x
specific heat capacity x temperature change
If the object cools then it gives out heat energy and if it heats up it takes
in heat energy.
Example
problems
1. How much heat energy is needed to raise the temperature of 3 kg of copper by
6 K?
(Specific heat capacity of copper = 385 J/(kg K)
Heat energy = mass x specific heat capacity x temperature change = 3 x 385x 6 =
6930J
2. What is the rise in temperature of 5 kg of water if it is given 84 000 J of
heat energy?
Specific heat capacity of water = 4200 J/(kg K).
Heat energy input = 84000 = 5x4200x temperature rise
Temperature rise = 84000/[5x4200] = 4 K
3. How much heat is lost by 3 kg of lead when it cools from 1000 oC
to 200 oC?
Specifc heat capacity of lead = 126 J/(kg K)
Heat energy given out = 3x126x80 = 30240J
4. A heater of 800W is use to heat a 600 g cast iron cooker plate.
How long will it take to raise the temperature of the plate by 200 oC?
Specific heat capacity of iron = 500 J/(kg K)
Heat energy needed = 0.6x500x200 = 60 000J
Time needed = 60 000/500 = 120 s = 2 minutes
Conversion of mechanical energy to heat
When an object falls to the ground, the potential energy that it had
at the top is converted to kinetic energy that finally becomes heat energy.
Assuming no loss of energy to any other forms we can work out the rise in
temperature of water falling over a high waterfall.
Example
problem
Height of waterfall 84 m.
Consider a mass of water m kg
Specific heat capacity of water = 4200 J/(kgoC).
Gravitational field of the Earth = 10 N/kg
Potential energy lost = Heat energy gained
m x10 x 84 = m x 4200 x temperature rise
Temperature rise = [10 x 84]/4200 = 0.2oC.
There must be no residual kinetic energy of spray and no sound must be made!
(Clearly not true but it is the best we can do without making the problem very
difficult).
This conversion of gravitational potential energy into heat energy can be used
in the laboratory to measure the specific heat capacity of lead shot.
Example
problem
Length of cardboard tube = 1 m
Mass of lead shot = m kg
The tube is upended ten times giving a total height fallen of 10m
Temperature rise 0.80 oC
Heat energy gained by the lead shot = potential energy lost by the lead shot
Expressed as a formula: m x specific heat capacity x 0.8 =m x10x10
Therefore specific heat capacity of lead = 10x10/0.8 = 125 J/(kgoC)
Derived
quantities that specify heat capacity as an intensive
property, i.e.,
independent of the size of a sample, are the molar heat capacity, which
is the heat capacity per mole of a pure substance, and the specific
heat capacity, often simply called specific heat, which is the heat
capacity per unit mass of a material. Occasionally, in engineering contexts, a volumetric heat capacity is used. Because heat capacities of materials tend to
mirror the number of atoms or particles they contain, when intensive heat
capacities of various substances are expressed directly or indirectly per
particle number, they tend to vary within a much more narrow range.
Temperature reflects the average kinetic energy of particles in matter while heat
is the transfer of thermal energy from high to low temperature regions. Thermal
energy transmitted by heat is stored as kinetic energy of atoms as they move, and in
molecules as they rotate. Additionally, some thermal energy may be stored as
the potential
energy associated
with higher-energy modes of vibration, whenever they occur in interatomic bonds
in any substance. Translation, rotation, and a combination of the two types of
energy in vibration (kinetic and potential) of atoms represent the degrees of freedom of motion which classically contribute to the heat
capacity of atomic matter (loosely bound electrons occasionally also
participate). On a microscopic scale, each system particle absorbs thermal
energy among the few degrees of freedom available to it, and at high enough
temperatures, this process contributes to a specific heat capacity that
classically approaches a value per mole of particles that is set by the Dulong-Petit law. This limit, which is about 25 joules per kelvin for each mole of atoms, is achieved by many solid
substances at room
temperature (see table
below).
For quantum
mechanical reasons, at any given temperature, some of these degrees of freedom
may be unavailable, or only partially available, to store thermal energy. In
such cases, the specific heat capacity will be a fraction of the maximum. As
the temperature approaches absolute zero, the specific heat capacity of a
system also approaches zero, due to loss of available degrees of freedom. Quantum theory can be used to quantitatively
predict specific heat capacities in simple systems.
Background
Before the development of modern thermodynamics, it was thought that heat
was a fluid, the so-called
caloric. Bodies were capable of holding a
certain amount of this fluid, hence the term
heat capacity, named and
first investigated by
Joseph Black in the 1750s.
[1]
Today one instead discusses the
internal
energy of a system. This is made up of its microscopic kinetic and
potential energy. Heat is no longer considered a fluid. Rather, it is a
transfer of disordered energy at the microscopic level. Nevertheless, at least
in English, the term "heat capacity" survives. Some other languages
prefer the term
thermal capacity, which is also sometimes used in
English.
Older units and English units
An older unit of heat is the
kilogram-calorie (Cal), originally defined as the energy
required to raise the temperature of one kilogram of water by one degree
Celsius, typically from 15 to 16 °C. The specific heat capacity of water
on this scale would therefore be exactly 1 Cal/(°C·kg). However, due to
the temperature-dependence of the specific heat, a large number of different
definitions of the calorie came into being. Whilst once it was very prevalent,
especially its smaller
cgs
variant the gram-calorie (cal), defined so that the specific heat of water
would be 1 cal/(K·g), in most fields the use of the calorie is now
archaic.
In the United States other units of measure for heat capacity may be quoted
in disciplines such as
construction,
civil
engineering, and
chemical engineering. A still common system is
the
English Engineering Units in which the
mass reference is
pound mass and the temperature is specified in
degrees
Fahrenheit or
Rankine. One (rare) unit of heat is the pound calorie
(lb-cal), defined as the amount of heat required to raise the temperature of
one pound of water by one degree Celsius. On this scale the specific heat of
water would be 1 lb-cal/(K·lb). More common is the
British thermal unit, the standard unit of
heat in the U.S. construction industry. This is defined such that the specific
heat of water is 1 BTU/(°F·lb).
Extensive and intensive quantities
An object's heat capacity (symbol
C) is defined as the ratio of the
amount of heat energy transferred to an object to the resulting increase in
temperature of the object,
In the International System of Units, heat capacity has the unit joules per
kelvin.
Heat capacity is an
extensive property, meaning it is a physical
property that scales with the size of a physical system. A sample containing
twice the amount of substance as another sample requires the transfer of twice
the amount of heat (
) to achieve the same change in temperature (
).
For many experimental and theoretical purposes it is more convenient to report
heat capacity as an
intensive property - an intrinsic characteristic
of a particular substance. This is most often accomplished by expressing the
property in relation to a unit of
mass. In science and engineering, such properties are often
prefixed with the term
specific.
[2]
International standards now recommend that specific heat capacity always refer
to division by mass.
[3]
The units for the
specific heat capacity are
.
In chemistry, heat capacity is often specified relative to one mole, the
unit of
amount of substance, and is called the
molar
heat capacity. It has the unit
.
For some considerations it is useful to specify the volume-specific heat
capacity, commonly called
volumetric heat capacity, which is the
heat capacity per unit volume and has SI units
. This is used almost exclusively for liquids and solids,
since for gases it may be confused with specific heat capacity
at constant
volume.
Metrology, the measurement of heat capacity
The heat capacity of most systems is not a constant. Rather, it depends on the
state variables of the thermodynamic system under study. In particular it is
dependent on temperature itself, as well as on the pressure and the volume of
the system, and the ways in which pressures and volumes have been allowed to
change while the system has passed from one temperature to another. The reason
for this is that pressure-volume work done to the system raises its temperature
by a mechanism other than heating, while pressure-volume work done
by
the system absorbs heat without raising the system's temperature.
Different measurements of heat capacity can therefore be performed, most
commonly either at constant
pressure or at constant
volume. The values thus measured are
usually subscripted (by
p and
V, respectively) to indicate the
definition.
Gases and
liquids are
typically also measured at constant volume. Measurements under constant
pressure produce larger values than those at constant volume because the
constant pressure values also include heat energy that is used to do
work to expand the substance against the
constant pressure as its temperature increases. This difference is particularly
notable in gases where values under constant pressure are typically 30% to
66.7% greater than those at constant volume.
[citation needed]
The specific heat capacities of substances comprising molecules (as distinct
from
monatomic
gases) are not fixed constants and vary somewhat depending on temperature.
Accordingly, the temperature at which the measurement is made is usually also
specified. Examples of two common ways to cite the specific heat of a substance
are as follows:
- Water (liquid):
cp = 4.1855 [J/(g·K)] (15 °C, 101.325 kPa)
- Water
(liquid): CvH = 74.539 J/(mol·K) (25 °C)
For liquids and gases, it is important to know the pressure to which given
heat-capacity data refer. Most published data are given for standard pressure.
However, quite different
standard conditions
for temperature and pressure have been defined by different organizations.
The
International Union
of Pure and Applied Chemistry (IUPAC) changed its recommendation from one
atmosphere to the round value 100 kPa
(≈750.062 Torr).
[notes 1]
Calculation from first principles
The
path integral Monte Carlo method is a
numerical approach for determining the values of heat capacity, based on
quantum dynamical principles. However, good approximations can be made for
gases in many states using simpler methods outlined below. For many solids
composed of relatively heavy atoms (atomic number > iron), at non-cryogenic
temperatures, the heat capacity at room temperature approaches 3
R =
24.94 joules per kelvin per mole of atoms (
Dulong–Petit law,
R is the
gas constant).
Low temperature approximations for both gases and solids at temperatures less
than their characteristic
Einstein temperatures or
Debye
temperatures can be made by the methods of Einstein and Debye discussed
below.
Thermodynamic relations and definition of heat
capacity
The internal energy of a closed system changes either by adding heat to the
system or by the system performing work. Written mathematically we have
For work as a result of an increase of the system volume we may write,
If the heat is added at constant volume, then the second term of this
relation vanishes and one readily obtains
This defines the
heat capacity at constant volume,
CV.
Another useful quantity is the
heat capacity at constant pressure,
CP.
With the
enthalpy of the system given by
our equation for d
U changes to
and therefore, at constant pressure, we have
Relation between heat capacities
Measuring the heat capacity, sometimes referred to as specific heat, at
constant volume can be prohibitively difficult for liquids and solids. That is,
small temperature changes typically require large pressures to maintain a
liquid or solid at constant volume implying the containing vessel must be
nearly rigid or at least very strong (see
coefficient of thermal expansion
and
compressibility). Instead it is easier to measure the
heat capacity at constant pressure (allowing the material to expand or contract
freely) and solve for the heat capacity at constant volume using mathematical
relationships derived from the basic thermodynamic laws. Starting from the
fundamental Thermodynamic Relation
one can show
where the partial derivatives are taken at constant volume and constant
number of particles, and constant pressure and constant number of particles,
respectively.
This can also be rewritten
where
The
heat capacity ratio or adiabatic index is the
ratio of the heat capacity at constant pressure to heat capacity at constant
volume. It is sometimes also known as the isentropic expansion factor.
Ideal gas
[4]
For an
ideal
gas, evaluating the partial derivatives above according to the
equation
of state where R is the gas constant for an ideal gas
→
=
→
substituting
=
this equation reduces simply to
Mayer's relation,
Specific heat capacity
The specific heat capacity of a material on a per mass basis is
which in the absence of phase transitions is equivalent to
where
is the heat capacity of a body made of the material in
question,
is the mass of the body,
is the volume of the body, and
is the density of the material.
For gases, and also for other materials under high pressures, there is need
to distinguish between different boundary conditions for the processes under
consideration (since values differ significantly between different conditions).
Typical processes for which a heat capacity may be defined include
isobaric
(constant pressure,
) or
isochoric (constant volume,
) processes. The corresponding specific heat capacities are expressed
as
From the results of the previous section, dividing through by the mass gives
the relation
A related parameter to
is
, the
volumetric heat capacity. In engineering
practice,
for solids or liquids often signifies a volumetric heat
capacity, rather than a constant-volume one. In such cases, the mass-specific
heat capacity (specific heat) is often explicitly written with the subscript
, as
. Of course, from the above relationships, for solids one
writes
For pure homogeneous
chemical compounds with established
molecular
or molar mass or a
molar quantity is established, heat capacity as an
intensive property can be expressed on a per
mole basis instead of a per mass basis by the
following equations analogous to the per mass equations:
= molar heat capacity at constant pressure
= molar heat capacity at constant volume
where n = number of moles in the body or
thermodynamic system. One may refer to such a
per
mole quantity as molar heat capacity to distinguish it from specific heat
capacity on a per mass basis.
Polytropic heat capacity
The
polytropic
heat capacity is calculated at processes if all the thermodynamic properties
(pressure, volume, temperature) change
= molar heat capacity at polytropic process
The most important polytropic processes run between the adiabatic and the
isotherm functions, the polytropic index is between
1 and the adiabatic
exponent (γ or κ)
Dimensionless heat capacity
The
dimensionless heat capacity of a material is
where
C is the heat capacity of
a body made of the material in question (J/K)
N is the number of
molecules in the body. (dimensionless)
In the
ideal
gas article, dimensionless heat capacity
is expressed as
, and is related there directly to half the number of degrees
of freedom per particle. This holds true for quadratic degrees of freedom, a
consequence of the
equipartition theorem.
More generally, the dimensionless heat capacity relates the logarithmic
increase in temperature to the increase in the
dimensionless entropy per particle
, measured in
nats.
Alternatively, using base 2 logarithms,
C* relates the
base-2 logarithmic increase in temperature to the increase in the dimensionless
entropy measured in
bits.
[5]
Heat capacity at absolute zero
From the definition of
entropy
the absolute entropy can be calculated by integrating from zero kelvins
temperature to the final temperature
Tf
The heat capacity must be zero at zero temperature in order for the above
integral not to yield an infinite absolute entropy, which would violate the
third law of thermodynamics. One of the
strengths of the
Debye model is that (unlike the preceding Einstein
model) it predicts the proper mathematical form of the approach of heat capacity
toward zero, as absolute zero temperature is approached.
Negative heat capacity (stars)
Most physical systems exhibit a positive heat capacity. However, even though
it can seem paradoxical at first,
[6][7]
there are some systems for which the heat capacity is
negative. These
include gravitating objects such as stars; and also sometimes some
nano-scale
clusters of a few tens of atoms, close to a phase transition.
[8]
A negative heat capacity can result in a
negative temperature.
According to the
virial theorem, for a self-gravitating body like a
star or an interstellar gas cloud, the average potential energy
UPot
and the average kinetic energy
UKin are locked together in
the relation
The total energy
U (=
UPot +
UKin)
therefore obeys
If the system loses energy, for example by radiating energy away into space,
the average kinetic energy and with it the average temperature actually
increases.
The system therefore can be said to have a negative heat capacity.
[9]
A more extreme version of this occurs with
black holes.
According to
black hole thermodynamics, the more mass
and energy a black hole absorbs, the colder it becomes. In contrast, if it is a
net emitter of energy, through
Hawking
radiation, it will become hotter and hotter until it boils away.
Theory of heat capacity
Factors that affect specific heat capacity
Molecules undergo many characteristic internal vibrations.
Potential energy stored in these internal degrees of freedom contributes to a
sample’s energy content,
[10]
[11]
but not to its temperature. More internal degrees of freedom tend to increase a
substance's specific heat capacity, so long as temperatures are high enough to
overcome quantum effects.
For any given substance, the heat capacity of a body is directly
proportional to the amount of substance it contains (measured in terms of mass
or moles or volume). Doubling the amount of substance in a body doubles its
heat capacity, etc.
However, when this effect has been corrected for, by dividing the heat
capacity by the quantity of substance in a body, the resulting
specific heat capacity is a function of the
structure of the substance itself. In particular, it depends on the number of
degrees of freedom that
are available to the particles in the substance, each of which type of freedom
allows substance particles to store energy. The translational
kinetic
energy of substance particles is only one of the many possible degrees of
freedom which manifests as
temperature change, and thus the larger the
number of degrees of freedom available to the particles of a substance
other
than translational kinetic energy, the larger will be the specific heat capacity
for the substance. For example, rotational kinetic energy of gas molecules
stores heat energy in a way that increases heat capacity, since this energy
does not contribute to temperature.
In addition, quantum effects require that whenever energy be stored in any
mechanism associated with a bound system which confers a degree of freedom, it
must be stored in certain minimal-sized deposits (quanta) of energy, or else
not stored at all. Such effects limit the full ability of some degrees of
freedom to store energy when their lowest energy storage quantum amount is not
easily supplied at the average energy of particles at a given temperature. In
general, for this reason, specific heat capacities tend to fall at lower
temperatures where the average thermal energy available to each particle degree
of freedom is smaller, and thermal energy storage begins to be limited by these
quantum effects. Due to this process, as temperature falls toward absolute
zero, so also does heat capacity.
Degrees of freedom
Molecules are quite different from the
monatomic
gases like
helium
and
argon. With
monatomic gases, thermal energy comprises only translational motions.
Translational motions are ordinary, whole-body movements in
3D space whereby particles move about and
exchange energy in collisions—like rubber balls in a vigorously shaken
container (see animation
here).
These simple movements in the three dimensions of space mean individual atoms
have three translational
degrees of freedom. A
degree of freedom is any form of energy in which heat transferred into an
object can be stored. This can be in
translational kinetic energy,
rotational kinetic energy, or other forms
such as
potential energy in
vibrational
modes. Only three translational degrees of freedom (corresponding to the
three independent directions in space) are available for any individual atom,
whether it is free, as a monatomic molecule, or bound into a polyatomic
molecule.
As to rotation about an atom's axis (again, whether the atom is bound or
free), its energy of rotation is proportional to the
moment
of inertia for the atom, which is extremely small compared to moments of
inertia of collections of atoms. This is because almost all of the mass of a
single atom is concentrated in its nucleus, which has a
radius
too small to give a significant moment of inertia. In contrast, the
spacing
of quantum energy levels for a rotating object is inversely proportional to its
moment of inertia, and so this spacing becomes very large for objects with very
small moments of inertia. For these reasons, the contribution from rotation of
atoms on their axes is essentially zero in monatomic gases, because the energy
spacing of the associated quantum levels is too large for significant thermal
energy to be stored in rotation of systems with such small moments of inertia.
For similar reasons, axial rotation around bonds joining atoms in diatomic
gases (or along the linear axis in a linear molecule of any length) can also be
neglected as a possible "degree of freedom" as well, since such
rotation is similar to rotation of monatomic atoms, and so occurs about an axis
with a moment of inertia too small to be able to store significant heat energy.
In polyatomic molecules, other rotational modes may become active, due to
the much higher moments of inertia about certain axes which do not coincide
with the linear axis of a linear molecule. These modes take the place of some
translational degrees of freedom for individual atoms, since the atoms are
moving in 3-D space, as the molecule rotates. The narrowing of quantum
mechanically determined energy spacing between rotational states results from
situations where atoms are rotating around an axis that does not connect them,
and thus form an assembly that has a large moment of inertia. This small
difference between energy states allows the kinetic energy of this type of
rotational motion to store heat energy at ambient temperatures. Furthermore
(although usually at higher temperatures than are able to store heat in
rotational motion) internal vibrational degrees of freedom also may become
active (these are also a type of translation, as seen from the view of each
atom). In summary, molecules are complex objects with a population of atoms
that may move about within the molecule in a number of different ways (see animation
at right), and each of these ways of moving is capable of storing energy if the
temperature is sufficient.
The heat capacity of molecular substances (on a "per-atom" or
atom-molar, basis) does not exceed the heat capacity of monatomic gases, unless
vibrational modes are brought into play. The reason for this is that
vibrational modes allow energy to be stored as potential energy in intra-atomic
bonds in a molecule, which are not available to atoms in monatomic gases. Up to
about twice as much energy (on a per-atom basis) per unit of temperature
increase can be stored in a solid as in a monatomic gas, by this mechanism of
storing energy in the potentials of interatomic bonds. This gives many solids
about twice the atom-molar heat capacity at room temperature of monatomic
gases.
However, quantum effects heavily affect the actual ratio at lower
temperatures (i.e., much lower than the melting temperature of the solid),
especially in solids with light and tightly bound atoms (e.g., beryllium metal
or diamond). Polyatomic gases store intermediate amounts of energy, giving them
a "per-atom" heat capacity that is between that of monatomic gases (
3⁄2
R per mole of atoms, where
R is the
ideal gas constant), and the maximum of fully
excited warmer solids (3
R per mole of atoms). For gases, heat capacity
never falls below the minimum of
3⁄2 R per mole (of molecules),
since the kinetic energy of gas molecules is always available to store at least
this much thermal energy. However, at cryogenic temperatures in solids, heat
capacity falls toward zero, as temperature approaches absolute zero.
Example of temperature-dependent specific heat
capacity, in a diatomic gas
To illustrate the role of various degrees of freedom in storing heat, we may
consider
nitrogen,
a
diatomic
molecule that has five active degrees of freedom at room temperature: the three
comprising translational motion plus two rotational degrees of freedom
internally. Although the constant-volume molar heat capacity of nitrogen at
this temperature is five-thirds that of monatomic gases, on a per-mole of atoms
basis, it is five-sixths that of a monatomic gas. The reason for this is the
loss of a degree of freedom due to the bond when it does not allow storage of
thermal energy. Two separate nitrogen atoms would have a total of six degrees of
freedom—the three translational degrees of freedom of each atom. When the atoms
are bonded the molecule will still only have three translational degrees of
freedom, as the two atoms in the molecule move as one. However, the molecule
cannot be treated as a point object, and the moment of inertia has increased
sufficiently about two axes to allow two rotational degrees of freedom to be
active at room temperature to give five degrees of freedom. The moment of
inertia about the third axis remains small, as this is the axis passing through
the centres of the two atoms, and so is similar to the small moment of inertia
for atoms of a monatomic gas. Thus, this degree of freedom does not act to
store heat, and does not contribute to the heat capacity of nitrogen. The heat
capacity
per atom for nitrogen (5/2 per mole molecules = 5/4 per mole
atoms) is therefore less than for a monatomic gas (3/2 per mole molecules or
atoms), so long as the temperature remains low enough that no vibrational
degrees of freedom are activated.
[12]
At higher temperatures, however, nitrogen gas gains two more degrees of
internal freedom, as the molecule is excited into higher vibrational modes that
store thermal energy. Now the bond is contributing heat capacity, and is
contributing more than if the atoms were not bonded. With full thermal
excitation of bond vibration, the heat capacity per volume, or per mole of gas
molecules
approaches seven-thirds that of monatomic gases. Significantly, this is
seven-sixths of the monatomic gas value on a mole-of-atoms basis, so this is
now a
higher heat capacity
per atom than the monatomic figure,
because the vibrational mode enables for diatomic gases allows an extra degree
of
potential energy freedom per pair of atoms, which monatomic gases
cannot possess.
[13]
See
thermodynamic temperature for more
information on translational motions, kinetic (heat) energy, and their
relationship to temperature.
However, even at these large temperatures where gaseous nitrogen is able to
store 7/6
ths of the energy
per atom of a monatomic gas
(making it more efficient at storing energy on an atomic basis), it still only
stores 7/12
ths of the maximal per-atom heat capacity of a
solid,
meaning it is not nearly as efficient at storing thermal energy on an atomic
basis, as solid substances can be. This is typical of gases, and results
because many of the potential bonds which might be storing potential energy in
gaseous nitrogen (as opposed to solid nitrogen) are lacking, because only one
of the spatial dimensions for each nitrogen atom offers a bond into which
potential energy can be stored without increasing the kinetic energy of the
atom. In general, solids are most efficient, on an atomic basis, at storing
thermal energy (that is, they have the highest per-atom or per-mole-of-atoms
heat capacity).
Per mole of...
Per mole of molecules
When the specific heat capacity,
c, of a material is measured
(lowercase
c means the unit quantity is in terms of mass), different
values arise because different substances have different
molar masses
(essentially, the weight of the individual atoms or molecules). In solids,
thermal energy arises due to the number of atoms that are vibrating.
"Molar" heat capacity
per mole of molecules, for both gases
and solids, offer figures which are arbitrarily large, since molecules may be
arbitrarily large. Such heat capacities are thus not intensive quantities for
this reason, since the quantity of mass being considered can be increased
without limit.
Per mole of atoms
Conversely, for
molecular-based substances (which also absorb heat
into their internal degrees of freedom), massive, complex molecules with high
atomic count—like octane—can store a great deal of energy per mole and yet are
quite unremarkable on a mass basis, or on a per-atom basis. This is because, in
fully excited systems, heat is stored independently by each atom in a
substance, not primarily by the bulk motion of molecules.
Thus, it is the heat capacity per-mole-of-atoms, not per-mole-of-molecules,
which is the intensive quantity, and which comes closest to being a constant
for all substances at high temperatures. This relationship was noticed
empirically in 1819, and is called the
Dulong-Petit
law, after its two discoverers.
[14]
Historically, the fact that specific heat capacities are approximately equal
when corrected by the presumed weight of the atoms of solids, was an important
piece of data in favor of the atomic theory of matter.
Because of the connection of heat capacity to the number of atoms, some care
should be taken to specify a mole-of-molecules basis vs. a mole-of-atoms basis,
when comparing specific heat capacities of molecular solids and gases. Ideal
gases have the same numbers of molecules per volume, so increasing molecular
complexity adds heat capacity on a per-volume and per-mole-of-molecules basis,
but may lower or raise heat capacity on a per-atom basis, depending on whether
the temperature is sufficient to store energy as atomic vibration.
In solids, the quantitative limit of heat capacity in general is about 3
R
per mole of atoms, where
R is the
ideal gas constant. This 3
R value is
about 24.9 J/mole.K. Six degrees of freedom (three kinetic and three potential)
are available to each atom. Each of these six contributes
1⁄2R specific heat capacity per mole of
atoms.
[15]
This limit of 3
R per mole specific heat capacity is approached at room
temperature for most solids, with significant departures at this temperature
only for solids composed of the lightest atoms which are bound very strongly,
such as
beryllium
(where the value is only of 66% of 3
R), or diamond (where it is only
24% of 3
R). These large departures are due to quantum effects which
prevent full distribution of heat into all vibrational modes, when the energy
difference between vibrational quantum states is very large compared to the
average energy available to each atom from the ambient temperature.
For monatomic gases, the specific heat is only half of 3
R per mole,
i.e. (
3⁄2R
per mole) due to loss of all potential energy degrees of freedom in these
gases. For polyatomic gases, the heat capacity will be intermediate between
these values on a per-mole-of-atoms basis, and (for heat-stable molecules)
would approach the limit of 3
R per mole of atoms, for gases composed of
complex molecules, and at higher temperatures at which all vibrational modes
accept excitational energy. This is because very large and complex gas
molecules may be thought of as relatively large blocks of solid matter which
have lost only a relatively small fraction of degrees of freedom, as compared
to a fully integrated solid.
Corollaries of these considerations for solids
(volume-specific heat capacity)
Since
the
bulk density of a solid chemical element is strongly
related to its molar mass (usually about 3
R per mole, as noted above),
there exists a noticeable inverse correlation between a solid’s density and its
specific heat capacity on a per-mass basis. This is due to a very approximate
tendency of atoms of most elements to be about the same size, despite much
wider variations in density and atomic weight. These two factors (constancy of
atomic volume and constancy of mole-specific heat capacity) result in a good
correlation between the
volume of any given solid chemical element and
its total heat capacity. Another way of stating this, is that the
volume-specific heat capacity (
volumetric heat capacity) of solid
elements is roughly a constant. The
molar
volume of solid elements is very roughly constant, and (even more reliably)
so also is the molar heat capacity for most solid substances. These two factors
determine the volumetric heat capacity, which as a bulk property may be
striking in consistency. For example, the element uranium is a metal which has
a density almost 36 times that of the metal lithium, but uranium's specific
heat capacity on a volumetric basis (i.e. per given volume of metal) is only
18% larger than lithium's.
Since the volume-specific corollary of the Dulong-Petit specific heat
capacity relationship requires that atoms of all elements take up (on average)
the same volume in solids, there are many departures from it, with most of
these due to variations in atomic size. For instance,
arsenic, which is
only 14.5% less dense than
antimony, has nearly 59% more specific heat capacity on a
mass basis. In other words; even though an ingot of arsenic is only about 17%
larger than an antimony one of the same mass, it absorbs about 59% more heat
for a given temperature rise. The heat capacity ratios of the two substances
closely follows the ratios of their molar volumes (the ratios of numbers of
atoms in the same volume of each substance); the departure from the correlation
to simple volumes in this case is due to lighter arsenic atoms being
significantly more closely packed than antimony atoms, instead of similar size.
In other words, similar-sized atoms would cause a mole of arsenic to be 63%
larger than a mole of antimony, with a correspondingly lower density, allowing
its volume to more closely mirror its heat capacity behavior.
Other factors
Hydrogen bonds
Hydrogen-containing
polar molecules like
ethanol,
ammonia, and
water have powerful,
intermolecular
hydrogen bonds when in their liquid phase. These
bonds provide another place where heat may be stored as potential energy of
vibration, even at comparatively low temperatures. Hydrogen bonds account for
the fact that liquid water stores nearly the theoretical limit of 3
R
per mole of atoms, even at relatively low temperatures (i.e. near the freezing
point of water).
Impurities
In the case of alloys, there are several conditions in which small impurity
concentrations can greatly affect the specific heat. Alloys may exhibit marked
difference in behaviour even in the case of small amounts of impurities being
one element of the alloy; for example impurities in semiconducting
ferromagnetic
alloys may lead to quite different specific heat properties.
[16]
The simple case of the monatomic gas
In the case of a monatomic gas such as
helium under
constant volume, if it is assumed that no electronic or nuclear quantum
excitations occur, each atom in the gas has only 3
degrees of freedom, all
of a translational type. No energy dependence is associated with the degrees of
freedom which define the position of the atoms. While, in fact, the degrees of
freedom corresponding to the
momenta of the atoms are quadratic, and thus contribute to
the heat capacity. There are
N atoms, each of which has 3 components of
momentum, which leads to 3
N total degrees of freedom. This gives:
where
is the heat capacity at constant volume of the gas
is the molar heat capacity at constant volume of the
gas
N is the total number of
atoms present in the container
The following table shows experimental molar constant volume heat capacity
measurements taken for each noble monatomic gas (at 1 atm and 25 °C):
|
Monatomic gas
|
CV,
m (J/(mol·K))
|
CV,
m/R
|
|
He
|
12.5
|
1.50
|
|
Ne
|
12.5
|
1.50
|
|
Ar
|
12.5
|
1.50
|
|
Kr
|
12.5
|
1.50
|
|
Xe
|
12.5
|
1.50
|
It is apparent from the table that the experimental heat capacities of the
monatomic noble gases agrees with this simple application of statistical
mechanics to a very high degree.
The molar heat capacity of a monatomic gas at constant pressure is then
Diatomic gas
Constant volume specific heat capacity of a diatomic gas
(idealised). As temperature increases, heat capacity goes from 3/2 R
(translation contibution only), to 5/2 R (translation plus rotation),
finally to a maximum of 7/2 R (translation + rotation + vibration)
In the somewhat more complex case of an ideal gas of
diatomic molecules, the presence of internal
degrees of freedom are apparent. In addition to the three translational degrees
of freedom, there are rotational and vibrational degrees of freedom. In
general, the number of degrees of freedom,
f, in a molecule with
na
atoms is 3
na:
Mathematically, there are a total of three rotational degrees of freedom,
one corresponding to rotation about each of the axes of three dimensional
space. However, in practice only the existence of two degrees of rotational
freedom for linear molecules will be considered. This approximation is valid
because the moment of inertia about the internuclear axis is vanishingly small
with respect to other moments of inertia in the molecule (this is due to the
very small rotational moments of single atoms, due to the concentration of
almost all their mass at their centers; compare also the extremely small radii
of the atomic nuclei compared to the distance between them in a diatomic
molecule). Quantum mechanically, it can be shown that the interval between
successive rotational energy
eigenstates is inversely proportional to the moment of
inertia about that axis. Because the moment of inertia about the internuclear
axis is vanishingly small relative to the other two rotational axes, the energy
spacing can be considered so high that no excitations of the rotational state
can occur unless the temperature is extremely high. It is easy to calculate the
expected number of vibrational degrees of freedom (or
vibrational
modes). There are three degrees of translational freedom, and two degrees
of rotational freedom, therefore
Each rotational and translational degree of freedom will contribute
R/2
in the total molar heat capacity of the gas. Each vibrational mode will
contribute
to the total molar heat capacity, however. This is because for
each vibrational mode, there is a potential and kinetic energy component. Both
the potential and kinetic components will contribute
R/2 to the total
molar heat capacity of the gas. Therefore, a diatomic molecule would be
expected to have a molar constant-volume heat capacity of
where the terms originate from the translational, rotational, and
vibrational degrees of freedom, respectively.
Constant volume specific heat capacity of diatomic gases
(real gases). The behavior between 200 K and 1000 K is a range not large enough
to both quantum transitions in all gases. Instead, at 200 K, all but hydrogen
are fully rotationally excited, so all have at least 5/2 R heat
capacity. (Hydrogen begins to fall below this value below room temp, but it
will require cryogenic conditions for even H2 to fall to 1.5 R). In the
other gases, only the heavier gases fully reach 7/2 R at the highest
temperature, due to the relatively small vibrational energy spacing of these
molecules. HCl and H2 begin to make the transition above 500 K, but have not
achieved it by 1000 K, since their vibrational energy-level spacing is too wide
to fully participate in heat capacity, even at this temperature.
The following is a table of some molar constant-volume heat capacities of
various diatomic gases at standard temperature (25
oC = 298 K)
|
Diatomic gas
|
CV,
m (J/(mol·K))
|
CV,
m / R
|
|
H2
|
20.18
|
2.427
|
|
CO
|
20.2
|
2.43
|
|
N2
|
19.9
|
2.39
|
|
Cl2
|
24.1
|
3.06
|
|
Br2 (vapour)
|
28.2
|
3.39
|
From the above table, clearly there is a problem with the above theory. All
of the diatomics examined have heat capacities that are lower than those
predicted by the
equipartition theorem, except Br
2.
However, as the atoms composing the molecules become heavier, the heat
capacities move closer to their expected values. One of the reasons for this
phenomenon is the quantization of vibrational, and to a lesser extent,
rotational states. In fact, if it is assumed that the molecules remain in their
lowest energy vibrational state because the inter-level energy spacings for
vibration-energies are large, the predicted molar constant volume heat capacity
for a diatomic molecule becomes just that from the contributions of translation
and rotation:
which is a fairly close approximation of the heat capacities of the lighter
molecules in the above table. If the quantum
harmonic oscillator approximation is made, it
turns out that the quantum vibrational energy level spacings are actually
inversely proportional to the square root of the
reduced
mass of the atoms composing the diatomic molecule. Therefore, in the case
of the heavier diatomic molecules such as chlorine or bromine, the quantum
vibrational energy level spacings become finer, which allows more excitations
into higher vibrational levels at lower temperatures. This limit for storing
heat capacity in vibrational modes, as discussed above, becomes 7R/2 = 3.5 R
per mole of gas molecules, which is fairly consistent with the measured value
for Br
2 at room temperature. As temperatures rise, all diatomic
gases approach this value.
General gas phase
The specific heat of the gas is best conceptualized in terms of the
degrees of freedom of an
individual molecule. The different degrees of freedom correspond to the
different ways in which the molecule may store energy. The molecule may store
energy in its translational motion according to the formula:
where
m is the mass of the molecule and
is velocity of the center of mass of the molecule. Each
direction of motion constitutes a degree of freedom, so that there are three
translational degrees of freedom.
In addition, a molecule may have rotational motion. The kinetic energy of
rotational motion is generally expressed as
where
I is the
moment
of inertia tensor of the molecule, and
is the
angular velocity pseudo-vector (in a coordinate
system aligned with the principle axes of the molecule). In general, then,
there will be three additional degrees of freedom corresponding to the
rotational motion of the molecule, (For linear molecules one of the inertia
tensor terms vanishes and there are only two rotational degrees of freedom).
The degrees of freedom corresponding to translations and rotations are called
the rigid degrees of freedom, since they do not involve any deformation of the
molecule.
The motions of the atoms in a molecule which are not part of its gross
translational motion or rotation may be classified as vibrational motions. It
can be shown that if there are
n atoms in the molecule, there will be as
many as
vibrational degrees of freedom, where
is the number of rotational degrees of freedom. A vibrational
degree of freedom corresponds to a specific way in which all the atoms of a
molecule can vibrate. The actual number of possible vibrations may be less than
this maximal one, due to various symmetries.
For example, triatomic nitrous oxide N
2O will have only 2 degrees
of rotational freedom (since it is a linear molecule) and contains n=3 atoms:
thus the number of possible vibrational degrees of freedom will be v =
(3*3)-3-2 = 4. There are four ways or "modes" in which the three
atoms can vibrate, corresponding to
1) A mode in which an atom at each
end of the molecule moves away from, or towards, the center atom at the same
time,
2) a mode in which either end atom moves asynchronously with
regard to the other two, and
3) and
4) two modes in which the
molecule bends out of line, from the center, in the two possible planar
directions that are
orthogonal to its axis. Each vibrational degree of freedom
confers TWO total degrees of freedom, since vibrational energy mode partitions
into 1 kinetic and 1 potential mode. This would give nitrous oxide 3
translational, 2 rotational, and 4 vibrational modes (but these last giving 8
vibrational degrees of freedom), for storing energy. This is a total of f =
3+2+8 = 13 total energy-storing degrees of freedom, for N
2O.
For a bent molecule like water H
2O, a similar calculation gives
9-3-3 = 3 modes of vibration, and 3 (translational) + 3 (rotational) + 6
(vibrational) = 12 degrees of freedom.
The storage of energy into degrees of freedom
If the molecule could be entirely described using classical mechanics, then
the theorem of
equipartition of energy could be used to
predict that each degree of freedom would have an average energy in the amount
of (1/2)
kT where
k is
Boltzmann’s constant and
T is the
temperature. Our calculation of the constant-volume heat capacity would be
straightforward. Each molecule would be holding, on average, an energy of (
f/2)
kT
where
f is the total number of degrees of freedom in the molecule.
Note that
Nk = R if
N is
Avogadro's number, which is the case in
considering the heat capacity of a mole of molecules. Thus, the total internal
energy of the gas would be (
f/2)
NkT where
N is
the total number of molecules. The heat capacity (at constant volume) would
then be a constant (
f/2)
Nk the mole-specific heat capacity
would be (
f/2)
R the molecule-specific heat capacity would
be (
f/2)
k and the dimensionless heat capacity would be just
f/2. Here again, each vibrational degree of freedom contributes 2f.
Thus, a mole of nitrous oxide would have a total constant-volume heat capacity
(including vibration) of (13/2)
R by this calculation.
In summary, the molar heat capacity (mole-specific heat capacity) of an
ideal gas with f degrees of freedom is given by
This equation applies to all polyatomic gases, if the degrees of freedom are
known.
[17]
The constant-pressure heat capacity for any gas would exceed this by an
extra factor of R (see
Mayer's relation, above). As example C
p
would be a total of (15/2)R/mole for nitrous oxide.
The effect of quantum energy levels in storing
energy in degrees of freedom
The various degrees of freedom cannot generally be considered to obey
classical mechanics, however. Classically, the energy residing in each degree
of freedom is assumed to be continuous—it can take on any positive value,
depending on the temperature. In reality, the amount of energy that may reside
in a particular degree of freedom is quantized: It may only be increased and
decreased in finite amounts. A good estimate of the size of this minimum amount
is the energy of the first excited state of that degree of freedom above its
ground state. For example, the first vibrational state of the hydrogen chloride
(HCl) molecule has an energy of about 5.74 × 10
−20 joule.
If this amount of energy were deposited in a classical degree of freedom, it
would correspond to a temperature of about 4156 K.
If the temperature of the substance is so low that the equipartition energy
of (1/2)
kT is much smaller than this excitation energy, then there
will be little or no energy in this degree of freedom. This degree of freedom
is then said to be “frozen out". As mentioned above, the temperature
corresponding to the first excited vibrational state of HCl is about
4156 K. For temperatures well below this value, the vibrational degrees of
freedom of the HCl molecule will be frozen out. They will contain little energy
and will not contribute to the thermal energy or the heat capacity of HCl gas.
Energy storage mode "freeze-out"
temperatures
It can be seen that for each degree of freedom there is a critical
temperature at which the degree of freedom “unfreezes” and begins to accept
energy in a classical way. In the case of translational degrees of freedom,
this temperature is that temperature at which the
thermal wavelength of the molecules is roughly
equal to the size of the container. For a container of macroscopic size (e.g.
10 cm) this temperature is extremely small and has no significance, since
the gas will certainly liquify or freeze before this low temperature is reached.
For any real gas translational degrees of freedom may be considered to always
be classical and contain an average energy of (3/2)
kT per
molecule.
The rotational degrees of freedom are the next to “unfreeze". In a
diatomic gas, for example, the critical temperature for this transition is
usually a few tens of kelvins, although with a very light molecule such as
hydrogen the rotational energy levels will be spaced so widely that rotational
heat capacity may not completely "unfreeze" until considerably higher
temperatures are reached. Finally, the vibrational degrees of freedom are
generally the last to unfreeze. As an example, for diatomic gases, the critical
temperature for the vibrational motion is usually a few thousands of kelvins,
and thus for the nitrogen in our example at room temperature, no vibration
modes would be excited, and the constant-volume heat capacity at room
temperature is (5/2)
R/mole, not (7/2)
R/mole. As seen above, with
some unusually heavy gases such as iodine gas I
2, or bromine gas Br
2,
some vibrational heat capacity may be observed even at room temperatures.
It should be noted that it has been assumed that atoms have no rotational or
internal degrees of freedom. This is in fact untrue. For example, atomic
electrons can exist in excited states and even the atomic nucleus can have
excited states as well. Each of these internal degrees of freedom are assumed
to be frozen out due to their relatively high excitation energy. Nevertheless,
for sufficiently high temperatures, these degrees of freedom cannot be ignored.
In a few exceptional cases, such molecular electronic transitions are of
sufficiently low energy that they contribute to heat capacity at room
temperature, or even at cryogenic temperatures. One example of an electronic
transition degree of freedom which contributes heat capacity at standard
temperature is that of nitric oxide (NO), in which the single electron in an
anti-bonding molecular orbital has energy transitions which contribute to the
heat capacity of the gas even at room temperature.
An example of a nuclear magnetic transition degree of freedom which is of
importance to heat capacity, is the transition which converts the
spin isomers of hydrogen gas (H
2)
into each other. At room temperature, the proton spins of hydrogen gas are
aligned 75% of the time, resulting in
orthohydrogen when they are. Thus,
some thermal energy has been stored in the degree of freedom available when
parahydrogen
(in which spins are anti-aligned) absorbs energy, and is converted to the
higher energy ortho form. However, at the temperature of liquid hydrogen, not
enough heat energy is available to produce orthohydrogen (that is, the
transition energy between forms is large enough to "freeze out" at
this low temperature), and thus the parahydrogen form predominates. The heat
capacity of the transition is sufficient to release enough heat, as
orthohydrogen converts to the lower-energy parahydrogen, to boil the hydrogen
liquid to gas again, if this evolved heat is not removed with a catalyst after
the gas has been cooled and condensed. This example also illustrates the fact
that some modes of storage of heat may not be in constant equilibrium with each
other in substances, and heat absorbed or released from such phase changes may
"catch up" with temperature changes of substances, only after a
certain time. In other words, the heat evolved and absorbed from the ortho-para
isomeric transition contributes to the heat capacity of hydrogen on long
time-scales, but not on
short time-scales. These time scales may also
depend on the presence of a catalyst.
Less exotic phase-changes may contribute to the heat-capacity of substances
and systems, as well, as (for example) when water is converted back and forth
from solid to liquid or gas form. Phase changes store heat energy entirely in
breaking the bonds of the potential energy interactions between molecules of a
substance. As in the case of hydrogen, it is also possible for phase changes to
be hindered as the temperature drops, so that they do not catch up and become
apparent, without a catalyst. For example, it is possible to
supercool
liquid water to below the freezing point, and not observe the heat evolved when
the water changes to ice, so long as the water remains liquid. This heat
appears instantly when the water freezes.
Solid phase
The dimensionless heat capacity divided by three, as a
function of temperature as predicted by the
Debye model
and by Einstein’s earlier model. The horizontal axis is the temperature divided
by the Debye temperature. Note that, as expected, the dimensionless heat
capacity is zero at absolute zero, and rises to a value of three as the
temperature becomes much larger than the Debye temperature. The red line
corresponds to the classical limit of the
Dulong-Petit
law
For matter in a crystalline solid phase, the
Dulong-Petit
law, which was discovered empirically, states that the mole-specific heat
capacity assumes the value 3
R. Indeed, for solid metallic chemical
elements at room temperature, molar heat capacities range from about 2.8
R
to 3.4
R. Large exceptions at the lower end involve solids composed of
relatively low-mass, tightly bonded atoms, such as
beryllium at
2.0
R, and
diamond
at only 0.735
R. The latter conditions create larger quantum vibrational
energy-spacing, so that many vibrational modes have energies too high to be
populated (and thus are "frozen out") at room temperature. At the
higher end of possible heat capacities, heat capacity may exceed
R by
modest amounts, due to contributions from anharmonic vibrations in solids, and
sometimes a modest contribution from
conduction electrons in metals. These are not
degrees of freedom treated in the Einstein or Debye theories.
The theoretical maximum heat capacity for multi-atomic gases at higher
temperatures, as the molecules become larger, also approaches the Dulong-Petit
limit of 3
R, so long as this is calculated per mole of atoms, not
molecules. The reason for this behavior is that, in theory, gases with very
large molecules have almost the same high-temperature heat capacity as solids,
lacking only the (small) heat capacity contribution that comes from potential
energy that cannot be stored between separate molecules in a gas.
The Dulong-Petit limit results from the
equipartition theorem, and as such is only
valid in the classical limit of a
microstate continuum, which is a high
temperature limit. For light and non-metallic elements, as well as most of the
common molecular solids based on carbon compounds at
standard ambient temperature,
quantum effects may also play an important role, as they do in multi-atomic
gases. These effects usually combine to give heat capacities lower than 3
R
per mole of
atoms in the solid, although in molecular solids, heat
capacities calculated
per mole of molecules in molecular solids may be
more than 3
R. For example, the heat capacity of water ice at the
melting point is about 4.6
R per mole of molecules, but only 1.5
R
per mole of atoms. As noted, heat capacity values far lower than 3
R
"per atom" (as is the case with diamond and beryllium) result from
“freezing out” of possible vibration modes for light atoms at suitably low
temperatures, just as happens in many low-mass-atom gases at room temperatures
(where vibrational modes are all frozen out). Because of high crystal binding
energies, the effects of vibrational mode freezing are observed in solids more
often than liquids: for example the heat capacity of liquid water is twice that
of ice at near the same temperature, and is again close to the 3
R per
mole of atoms of the Dulong-Petit theoretical maximum.
For a more modern and precise analysis of the heat capacities of solids,
especially at low temperatures, it is useful to use the idea of
phonons. See
Debye model.
Phonons can also be applied to the heat capacity of liquids
[18]
The specific heat of amorphous materials has characteristic discontinuities
at the glass transition temperature due to rearrangements that occur in the
distribution of atoms.
[19]
These discontinuities are frequently used to detect the glass transition
temperature where a supercooled liquid transforms to a glass.
[20]
Table of specific heat capacities
Note that the especially high
molar values, as for paraffin,
gasoline, water and ammonia, result from calculating specific heats in terms of
moles of
molecules. If specific heat is expressed per mole of
atoms
for these substances, none of the constant-volume values exceed, to any large
extent, the theoretical
Dulong-Petit limit of 25 J/(mol·K) = 3
R
per mole of atoms (see the last column of this table). Paraffin, for example,
has very large molecules and thus a high heat capacity per mole, but as a
substance it does not have remarkable heat capacity in terms of volume, mass,
or atom-mol (which is just 1.41 R per mole of atoms, or less than half of most
solids, in terms of heat capacity per atom).
In the last column, major departures of solids at standard temperatures from
the
Dulong-Petit law value of 3R, are usually due to
low atomic weight plus high bond strength (as in diamond) causing some vibration
modes to have too much energy to be available to store thermal energy at the
measured temperature. For gases, departure from 3R per mole of atoms in this
table is generally due to two factors:
(1) failure of the higher
quantum-energy-spaced vibration modes in gas molecules to be excited at room
temperature, and
(2) loss of potential energy degree of freedom for
small gas molecules, simply because most of their atoms are not bonded
maximally in space to other atoms, as happens in many solids.
|
Notable minima and
maxima are shown in maroon
|
|
Table of specific
heat capacities at 25 °C (298 K) unless otherwise noted
Substance
|
|
(mass) specific
heat capacity
cp or cm
J·g−1·K−1
|
Constant
pressure molar
heat capacity
Cp,m
J·mol−1·K−1
|
Constant
volume molar
heat capacity
Cv,m
J·mol−1·K−1
|
|
Constant vol.
atom-molar
heat capacity
in units of R
Cv,m(atom)
atom-mol−1
|
Air (Sea level, dry,
0 °C (273.15 K))
|
gas
|
1.0035
|
29.07
|
20.7643
|
0.001297
|
~ 1.25 R
|
|
Air (typical
room conditionsA)
|
gas
|
1.012
|
29.19
|
20.85
|
0.00121
|
~ 1.25 R
|
|
|
solid
|
0.897
|
24.2
|
|
2.422
|
2.91 R
|
|
|
liquid
|
4.700
|
80.08
|
|
3.263
|
3.21 R
|
|
|
mixed
|
3.5
|
|
|
3.7*
|
|
|
|
solid
|
0.207
|
25.2
|
|
1.386
|
3.03 R
|
|
|
gas
|
0.5203
|
20.7862
|
12.4717
|
|
1.50 R
|
|
|
solid
|
0.328
|
24.6
|
|
1.878
|
2.96 R
|
|
|
solid
|
1.82
|
16.4
|
|
3.367
|
1.97 R
|
|
|
solid
|
0.123
|
25.7
|
|
1.20
|
3.09 R
|
|
|
solid
|
0.231
|
26.02
|
|
|
3.13 R
|
|
|
gas
|
0.839*
|
36.94
|
28.46
|
|
1.14 R
|
|
|
solid
|
0.449
|
23.35
|
|
|
2.81 R
|
|
|
solid
|
0.385
|
24.47
|
|
3.45
|
2.94 R
|
|
|
solid
|
0.5091
|
6.115
|
|
1.782
|
0.74 R
|
|
|
liquid
|
2.44
|
112
|
|
1.925
|
1.50 R
|
|
|
liquid
|
2.22
|
228
|
|
1.64
|
1.05 R
|
|
|
solid
|
0.84
|
|
|
|
|
|
|
solid
|
0.129
|
25.42
|
|
2.492
|
3.05 R
|
|
|
solid
|
0.790
|
|
|
2.17
|
|
|
|
solid
|
0.710
|
8.53
|
|
1.534
|
1.03 R
|
|
|
gas
|
5.1932
|
20.7862
|
12.4717
|
|
1.50 R
|
|
|
gas
|
14.30
|
28.82
|
|
|
1.23 R
|
|
|
gas
|
1.015*
|
34.60
|
|
|
1.05 R
|
|
|
solid
|
0.450
|
|
|
3.537
|
3.02 R
|
|
|
solid
|
0.129
|
26.4
|
|
1.44
|
3.18 R
|
|
|
solid
|
3.58
|
24.8
|
|
1.912
|
2.98 R
|
|
|
liquid
|
4.379
|
30.33
|
|
2.242
|
3.65 R
|
|
|
solid
|
1.02
|
24.9
|
|
1.773
|
2.99 R
|
|
|
liquid
|
0.1395
|
27.98
|
|
1.888
|
3.36 R
|
|
|
gas
|
2.191
|
35.69
|
|
|
0.66 R
|
|
|
liquid
|
2.14
|
68.62
|
|
|
1.38 R
|
|
|
gas
|
1.040
|
29.12
|
20.8
|
|
1.25 R
|
|
|
gas
|
1.0301
|
20.7862
|
12.4717
|
|
1.50 R
|
|
|
gas
|
0.918
|
29.38
|
21.0
|
|
1.26 R
|
|
|
solid
|
2.5 (ave)
|
900
|
|
2.325
|
1.41 R
|
|
|
solid
|
2.3027
|
|
|
|
|
|
|
liquid
|
2.9308
|
|
|
|
|
|
|
solid
|
0.703
|
42.2
|
|
1.547
|
1.69 R
|
|
|
solid
|
0.233
|
24.9
|
|
2.44
|
2.99 R
|
|
|
solid
|
1.230
|
28.23
|
|
|
3.39 R
|
|
|
solid
|
0.466
|
|
|
|
|
|
|
solid
|
0.227
|
27.112
|
|
|
3.26 R
|
|
|
solid
|
0.523
|
26.060
|
|
|
3.13 R
|
|
|
solid
|
0.134
|
24.8
|
|
2.58
|
2.98 R
|
|
|
solid
|
0.116
|
27.7
|
|
2.216
|
3.33 R
|
|
|
gas
|
2.080
|
37.47
|
28.03
|
|
1.12 R
|
|
|
liquid
|
4.1813
|
75.327
|
74.53
|
4.1796
|
3.02 R
|
|
|
liquid
|
4.1813
|
75.327
|
74.53
|
4.2160
|
3.02 R
|
|
|
solid
|
2.11
|
38.09
|
|
1.938
|
1.53 R
|
|
|
solid
|
0.387
|
25.2
|
|
2.76
|
3.03 R
|
|
Substance
|
|
Cp
J/(g·K)
|
Cp,m
J/(mol·K)
|
Cv,m
J/(mol·K)
|
|
|
A Assuming an altitude of 194 metres above mean sea level (the
world–wide median altitude of human habitation), an indoor temperature of 23
°C, a dewpoint of 9 °C (40.85% relative humidity), and 760 mm–Hg sea
level–corrected barometric pressure (molar water vapor content = 1.16%).
*Derived data by calculation. This is for
water-rich tissues such as brain. The whole-body average figure for mammals is
approximately 2.9 J/(cm3·K) [27]
Specific heat capacity of building materials
(Usually of interest to builders and solar designers)
|
Specific heat
capacity of building materials
|
|
Substance
|
Phase
|
cp
J/(g·K)
|
|
|
solid
|
0.920
|
|
|
solid
|
0.840
|
|
|
solid
|
0.880
|
|
|
solid
|
0.840
|
|
|
solid
|
0.670
|
|
|
solid
|
0.503
|
|
|
solid
|
0.753
|
|
|
solid
|
0.790
|
|
|
solid
|
1.090
|
|
|
solid
|
0.880
|
|
|
solid
|
0.835
|
|
|
solid
|
0.800
|
|
|
gas
|
0.664
|
|
|
solid
|
1.7 (1.2 to 2.3)
|
|
Substance
|
Phase
|
cp
J/(g·K)
|
