Statistical Physics PDF

Summary

These lecture notes cover fundamental concepts in Statistical Physics, including heat transfer, heat capacity, specific heat, and phase transitions. The topics are presented with clear explanations and diagrams.

Full Transcript

STATISTICAL
PHYSICS
Mr. P.R.S.Tissera
Department of Physical Sciences
Faculty of Applied Sciences
Sabaragamuwa University of Sri Lanka
 HEAT: ENERGY IN TRANSIT
 Heat is energy that flows between a system and its environment
by virtue of a temperature difference between them

Figure 1 : (a) If the temperature TS of a system is less than the temperature TE of
its environment, heat flows into the system until thermal equilibrium
is established as in (b). (c) If the temperature of a system is greater
than that of its environment, heat flows out of the system

2
 Because heat is a form of energy, its units are those of energy,
namely the joule (J), the calorie (cal), and the British thermal unit
(Btu)

1 cal = 4.186 J and 1 Btu = 1055 J

 Heat is similar to work in that both represent a means for the
transfer of energy

 Neither heat nor work is an intrinsic property of a system; that is
we can not say that a system contains a certain amount of heat or
work

3
HEAT CAPACITY AND SPECIFIC HEAT
 We can change the state of a body by transferring energy to or
from it in the form of heat, or by doing work on the body

 One property of a body that may change in such a process is its
temperature T

 Let, the change in temperature T corresponds to the transfer of a
particular quantity of heat energy Q, it is convenient to define the
heat capacity C of a body as the ratio of the amount of heat Q
supplied to a body in any process to its corresponding
temperature change T; that is,

Q
C 
T
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 The heat capacity per unit mass of a body, called specific heat
capacity

C Q
c  
m m T

 The specific heat capacity ‘c’ depends on the temperature T

 Therefore, the heat that must be given to a body of mass ‘m’
whose material has a specific heat ‘c’, to increase temperature
from initial temperature ‘Ti’ to final temperature ‘Tf ’ is given
by
Tf

Q  m 
Ti
c dT

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 ‘c’ may be a function of the temperature

 At ordinary temperatures and over ordinary temperature
intervals, specific heats can be considered to be constants

 Under these conditions, we can therefore write

Q  m c  Tf  Ti 

 If mass is very small, then

Q  n c v  Tf  Ti 

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Table 1 : Heat capacities of some substances
Substance Specific heat capacity Molar heat capacity
(J kg1 K1) (J mol1 K1)

Elemental solids
Tungsten 135 24.8
Silver 236 25.5
Copper 387 24.6
Carbon 502 6.02
Aluminum 900 24.3

Other solids
Brass 380
Granite 790
Ice (10C) 2220

Liquids
Ethyl alcohol 2430
Seawater 3900
Water 4190

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 HEAT OF TRANSFORMATION
 When heat enters a solid or liquid, the temperature of the sample
does not necessarily rise

 Instead, the sample may change from one phase or state (that is,
solid, liquid, or gas) to another

 The minimum amount of heat per unit mass transferred during a
phase change is called the heat of transformation or latent heat
(symbol L) for the process
Q
L 
m
Where ‘m’ is the mass of the sample
Q  mL that changes phase

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  The heat transferred during melting or freezing is called the heat
of fusion (symbol Lf), and the heat transferred during boiling or
condensing is called the heat of vaporization (symbol Lv)

Table 2 : Some heat of transformation

Substance Melting Point Heat of Fusion Boiling Point Heat of Vaporization
(K) (kJ kg1) (K) (kJ kg1)

Hydrogen 14.0 58.6 20.3 452
Oxygen 54.8 13.8 90.2 213
Mercury 234 11.3 630 296
Water 273 333 373 2256
Lead 601 24.7 2013 858
Silver 1235 105 2485 2336
Copper 1356 205 2840 4730

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HEAT CAPACITIES OF AN IDEAL GAS

Heat Capacity at Constant Volume
 Let us introduce a certain amount of energy as heat Q into a gas
that is confined inside a cylinder fitted with a piston

 The gas can either
1. Store the energy as the random kinetic energy of its
molecules (internal energy) or
2. Use the energy to do work on the environment (such as
by raising a weight on the piston)

10
 Let us first consider the case in which the piston is fixed, so that
the volume of the gas remains constant, and no external work is
done

 In this case all the heat energy goes into internal energy:

Q  E int

 Molar heat capacity at constant volume

Q E int
CV  
n T n T

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Monatomic Ideal Gas
3
E int  n R T
2

3
n R T
3
CV  2  R  12.5 J mol1 K 1
n T 2

Diatomic Ideal Gas
5
E int  n R T
2

5
n R T
5
CV  2  R  20.8 J mol1 K 1
n T 2

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Polyatomic Ideal Gas

E int  3 n R T

3 n R T
CV   3 R  24.1 J mol 1 K 1
n T

 Molar heat capacity at constant volume only depends on the
number of atoms in the system

13
 Heat Capacity at Constant Pressure

Figure 2 : Two idealgas isotherms differing in temperature by T are
connected by the constantvolume process ab and the
constantpressure process ac
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 Already we have established that the internal energy of an ideal
gas depends only on the temperature

 For all paths connecting the two isotherms of above figure, the
change in internal energy has the same value, because all paths
correspond to the same change in temperature

 In particular, the change in internal energy is the same for paths
ab and ac

E int, ab  E int, ac

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 There are two contributions to the change in internal energy along
path ac

 They are;
 the heat Q transferred to the gas, and
 the work W done on the gas

E int, ac  Q  W

 The work done and heat exchanged along path ac, respectively

W   P V   n R T and
Q  n C P T

 And also E int, ab  n C V T

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 E int, ac  E int, ab

n C V T  n C P T   n R T 

CP  CV  R

CP 
5
R  20.8 J mol 1 K 1 monatomic gas 
2

CP 
7
R  29.1 J mol 1 K 1 diatomic gas 
2

C P  4 R  33.3 J mol 1 K 1 polyatomic gas 

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Ratio of molar heat capacities 

CP
 
CV

 
5
 1.67 monatomic gas 
3

 
7
 1.40 diatomic gas 
5

 
4
 1.33 polyatomic gas 
3
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Table 3 : Molar heat capacities of gases
Gas CP CV CP  CV 
(J mol1 K1) (J mol1 K1) (J mol1 K1)

Monatomic
Ideal 20.8 12.5 8.3 1.67
He 20.8 12.5 8.3 1.66
Ar 20.8 12.5 8.3 1.67

Diatomic
Ideal 29.1 20.8 8.3 1.40
H2 28.8 20.4 8.4 1.41
N2 29.1 20.8 8.3 1.40
O2 29.4 21.1 8.3 1.40

Polyatomic
Ideal 33.3 24.1 8.3 1.33
CO2 37.0 28.5 8.5 1.30
NH3 36.8 27.8 9.0 1.31
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 Example
A family enters a winter vacation cabin that has been unheated for such a
long time that the interior temperature is the same as the outside
temperature (0C). The cabin consists of a single room of floor area 6m
by 4m and height 3m. The room contains one 2 kW electric heater.
Assuming that the room is perfectly airtight and that all the heat from the
electric heater is absorbed by the air, none escaping through the walls or
being absorbed by the furniture, how long after the heater is turned on
will the air temperature reach the comfort level of 21C? (Assume that the
air in the room behaves like an ideal diatomic gas.)

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ANSWER

21
 THE FIRST LAW OF
THERMODYNAMICS

Figure 3 : Two gases separated by a diathermic (heat conducting) wall
in an insulated container

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 After a sufficient time in thermal contact the system comes to
equilibrium at some intermediate temperature T

 By this time,

The energy lost as The energy gained as
heat by the hotter gas =
heat by the cooler gas
(Q1) (Q2)

Q1  Q 2

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 Instead of taking the combination as our system, let us choose
gas 2, which absorbs heat Q2

 After this energy is absorbed, there is no change in the system
other than an increase of its temperature from T2 to T

 For an ideal gas, we can calculate the corresponding change in
internal energy Eint, 2

 The only source for this change in internal energy is the
absorbed heat, and so
E int, 2  Q 2 , both quantities being positive

 Similar statement of conservation of energy applied to gas 1
E int, 1  Q1 , both quantities are negative

 General equation E int  Q

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Figure 4 : A gases in an insulated container has external work done on it
by gravity
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 Suppose that the load on the piston is gradually increased, so
that the weighted piston descends through a certain distance

 Gravity does a certain amount of work W on the system

 The temperature increases in this process, and the system
therefore experiences a positive change in internal energy

 Since no heat transfer is involved, the internal energy of the gas
increases by the work done on it, or

E int  W both quantities being positive

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Figure 5 : (a) A system in an initial state in equilibrium with its
surroundings (b) A thermodynamic process during
which the system may exchange heat Q or work W with
its environment. (c) A final equilibrium state reached as
a result of the process

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 The system starts out
in an initial
equilibrium state ‘i’
in which the
thermodynamic
variables have certain
values

 Finally, the system is
in a final equilibrium
state ‘f’

 Now take the system
from state ‘i’ to state
‘f’ along a variety of Figure 6 : A system in an initial equilibrium state
different paths ‘i’ is brought to a final equilibrium
state ‘f’ along three different paths

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 Both W and Q depend on the path

 Guided by our previous discussion of internal energy, we
evaluate the quantity Q + W for each path

 We find that in every case the quantity Q + W has the same
value

 Even though Q and W individually depends on the path taken,
the quantity Q + W is independent of the path, depending only
on the initial and final equilibrium states ‘i’ and ‘f’ of the gas

 This brings us to the first law of thermodynamics

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 First law of thermodynamics

In any thermodynamic process between equilibrium states ‘i’ and ‘f’,
the quantity Q + W has the same value for any path between ‘i’ and
‘f’. This quantity is equal to the change in the value of a state
function called the internal energy

 Mathematically, the first law is

E int  Q  W

 If the system undergoes only an infinitesimal change in state, only
an infinitesimal amount of heat dQ is absorbed and only an
infinitesimal amount of work dW is done. In such a case the first
law is written in differential form
dE int  dQ  dW
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APPLICATION OF THE FIRST LAW

Adiabatic Process
 In an adiabatic process, the system is well insulated so that no
heat enters or leaves, in which case dQ = 0
dE int  dQ  dW

dE int  0  dW

dE int  dW adiabatic process
 We know that dE int  n CV dT
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Thus P dV   dW   dE int   n C V dT

P dV   n C V dT A 

d PV  d n R T

P dV  V dP  n R dT

V dP  n R dT  P dV  n R dT  n C V dT  n dT R  C V 

V dP  n dT C P B

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B V dP
 
n dT C P C
 P  
A  P dV n dT C V CV

dP dV
  
P V
Pf Vf
dP dV

pi
P
   
Vi
V

Pf Vf
ln    ln
Pi Vi

Pi Vi  Pf Vf

P V   constant
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 We can rearrange these results in terms of temperature, using
the ideal gas equation of state

P V  V   1  constant

k T  V   1  constant

T V   1  constant

 Also, we have already shown

W 
1
 Pf Vf  Pi Vi  (adiabatic process)
  1 

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 Isothermal Process
 In an isothermal process, the temperature remains constant
 If the system is an ideal gas, then the internal energy must
therefore remains constant

E int  0

Q  W  0 Q  W

 If an amount of positive work W is done on the gas, an equivalent
amount of heat Q = W is released by the gas to the environment

 None of the work done on the gas remains with the gas as stored
internal energy

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 Constant Volume Process
 If the volume of the gas remains constant, it can do no work

 Thus

W 0
and

E int  Q constant volume process 

 In this case all the heat that enters the gas is stored as internal
energy

36
 Cyclical Process
 In a cyclical process, we carry out a sequence of operations that
eventually restores the system to its initial state

Figure 7 : A gas undergoes a cyclical process starting at point A
37
 Because the process starts and finishes at the point A, the internal
energy change for the cycle is zero

 Thus,

Q  W  0 cyclical process 
Where Q and W represent the totals for the cycle

 The work done W0 Path 1
W0 Path 2
W0 Path 3

W0 cyclical process

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 Thus, the heat exchange

Q  W cyclical process 
Q0 cyclical process 

 For any cycle that is done in a counterclockwise direction,

W  0 and Q  0

 For any cycle that is done in a clockwise direction,

W  0 and Q  0

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 Free Expansion

Figure 8 : Free expansion. Opening the stopcock allows gas to flow from
one side of the insulating container to the other. No work is
done, and no heat is transferred to the environment

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 No work is done in this process

 The process is adiabatic

 Hence, with W = 0 and Q = 0, the first law gives

E int  0 Free expansion 

 Thus the internal energy of an ideal gas undergoing a free
expansion remains constant

 Because the internal energy of an ideal gas depends only
on the temperature, its temperature must similarly remain
constant

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Table 4 : Application of the First Law

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EXAMPLE

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Answer

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45
46
47
END OF THE CHAPTER - 6

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