Thermodynamics Lecture Notes PDF

Summary

These lecture notes cover the fundamental concepts of thermodynamics, including the first law of thermodynamics, isothermal and adiabatic processes, and calculations for ideal gases. The notes include examples and calculations.

Full Transcript

First law of thermodynamic
E = q – P  V qv= E qp = H
 E 
C v    H   E    V 
C    C p  C v    + P 
  T v p
  T p  V  T

 T  

Work done by free expansion = 0
 E  CP – CV = R for ideal gad
   0 Joule experiment
 V T

Isothermal reversible process
V2 P1 E = 0
w  n R T ln w  n R T ln
V1 P2 H  0
 Work in reversible isothermal
V2 P1 E= H = 0
q  w  n R T ln q  w  n R T ln
V1 P2
Work in irreversible isothermal

P2
w = q = nRT(1- ) E= H = 0
P1
in reversible adiabatic Decrease of internal energy results in the
lowering of temperature in case of adiabatic
q=0 expansion
E = - w
increase of temperature for adiabatic
compression
E = nCV (T2 – T1) = -w
w= nCV (T1 – T2) H = nCp (T2 – T1)
Relation between temperature and volume in reversible
adiabatic process
dE= dq - dw dE= dq – pdv

 E 
C v    dE = nCV dT
  T v

For adiabatic expansion dq = 0 then we get dE = – pdv
nCv dT = -PdV for an ideal gas pv = nRT
n RT C v dT dV
nCv dT   dV  
R T V
V
 T 2 V 2
C v dT dV
   
R T1
T V1
V

Integration between suitable limits, we get
C v T2 V1
ln  ln 2
R T1 V2 X Y
1/
 T2 
CV / R
V1 X Y
ln    ln
 T1  V2 R/
 T2   V1 
C V /R
 T2   V1
      
Taking antilogarithm, we have T1  V2 
 T1   V2 
 CP – CV = R

CP -CV /CV
CP /CV 1
T2  V1  T2  V1 
   
T1  V2  T1  V2 

1
T2  V1 
  
T1  V2   = Cp / Cv > 1

R / Cv  1
T2 V2  T1V1
Relation between pressure and temperature in reversible adiabatic process
R /C V
T2  V1 
    V = RT / P
T1  V2 
R / CV R/C V R/C V
T2  RT1 / P1  T2  T1   P2 
       
T1  RT2 / P2  T1  T2   P1 
R/CV R/CV
 T2   T2   P2 
      
 T1   T1   P1 
1 R / C V R / CV CV  R / CV R / CV
 T2   P2   T2   P2 
        
 T1   P1   T1   P1 
CP / CV R / CV R CV
 T2   P2   T 2   P2 
*
CV C P
        
 T1   P1   T1   P1 
 R / CP CP CV / CP
T2  P2  T2  P2 
      
T1  P1  T1  P1 

1
1
T2  P2  
  
T1  P1 
Relation between pressure and volume in reversible adiabatic process
R/CV R / CP
T2  V1  T2  P2 
       
T1  V2  T1  P1 
R / CP R / CV
 P2   V1 
    
 P1   V2 
CP/CV
 P2   V1 
    
 P1   V2 
 

 P2   V1 
     PV PV
1 1
2 2
 P1   V2 
Example
A quantity of air at 25oC, is compressed adiabatically and
reversibly from a volume of 10 liters to 1 liter Assuming ideal
behaviour and taking CV (for air) = 5 cal. deg-1 mole-1 calculate
the final temperature of air.
R /C V
T  V 
2   1 
T V 
1  2 
T
2  ( 1 0 ) 2 /5
298 1
T  749o K  476oC
2
omework

xample
quantity of air is allowed to expand adiabatically and reversibly from 200
m. to 20 atm assuming ideal behaviour calculate the final temperature if
he initial temperature is 25oC and Cv = 5 cal deg-1 mole-1
 1 Cal = 4.18 J , 1 J = 107 erg
Example
Calculate the work of compression in ergs when the
pressure of 1 mole of an ideal gas is changed adiabatically
and reversibly from 1 to 5 atm, initial temp 25oC (Cv = 5 cal
mole-1 deg-1).
w = n CV (T1 – T2) P2 R/C
w  n C V T1 [1  ( )
P1
T2 P2 R/CP P2 R/CP
( ) T2  T1 ( ) 5 2/7
T1 P1 P1  5  298 [1  ( ) ] c
1
5
Cp = 5 + 2 = 7 cal deg-1 mole-1  5  298  4.18 107 [1  ( ) 2/7
1
  3.64  1010 ergs
 Adiabatic Irreversible Expansion
In an irreversible expansion the pressure is constant and
the work of expansion is given by

w  P2dV= P2 (V2 V)
1
irr
Energy change

Since q = 0 for adiabatic changes, the first law equation gives
E = -w= -P2 (V2 – V1)

E = nCV (T2 – T1) Also

E = nCV (T2 – T1) = - P2 (V2 – V1) = P2(V1 – V2)
 E = nCV (T2 – T1) = P2(V1 – V2)

 n R T1 nR T 2

nC V (T 2 - T 1 ) = P2   
 P1 P2 

P2
C v (T2  T1 )  RT1  RT2
P1

C v  ( P2 / P1 ) R
T 2  T1
Cp
From the last equation we can calculate T2 and hence E
Enthalpy change
H= n CP (T2 – T1)

Using the value of T2 from equation

C v  (P2 / P1 )R
T2  T1
Cp

H can be evaluated.
Homework
Example
One mole of an ideal gas at 300 K and 10 atm expand to 1 atm both
reversibly and irreversibly under isothermal and adiabatic
conditions. Calculate w. q, E and H for (a) Isothermal-reversible,
(b) isothermal-irreversible (c) adiabatic-reversible and (d) adiabatic-
irreversible expansion of the gas. (Given that CV = 3/2 R)
 Comparison between isothermal and adiabatic process
Plot P versus V for the isothermal and adiabatic reversible expansion for
ideal gas from the same initial point to the final points
The higher curve which has the lower negative
slope represents the isothermal reversible
expansion
the lower curve which has the higher negative
slope represents the adiabatic reversible
expansion.
To prove that, comparison between adiabatic an
isothermal process.
Calculation of the slope of each process as
follows.
lope for reversible isothermal expansion can be obtained from the general
quation PV = RT. P = RT/ V

dP RT RT 1 P
- 2   
dV V V V V
For the adiabatic reversible expansion we use the equation,
-γ
PV = constant, P = constant V
dP - γ -1 dP γ -γ -1 P
  γ const V   γPV V   γPV -1   γ
dV dV V

 > 1,  The slope in case of adiabatic reversible expansion is lower than the isothermal expansion.
The area under the P-V carve for the same volume expansion is greater in isothermal reversi
expansion than adiabatic reversible expansion.
Example
One mole of benzene is converted reversibly into vapour at its boiling
point 80.2oC by supplying heat. The vapour expands against the pressure
of 1 atm. The heat of vaporization of benzene is 395 J/g. Calculate q,w, 
and H for the process.

The process is
C6H6(liquid) C6H6 (vapour)

Heat supplied for conversion of 1 mole of benzene into its vapour
q = Heat of vaporization per gm. × mol. Wt. of benzene
= 395 × 78
q = 30810 J mol-1.
w= PV = P(Vv – VL)
= PVv if Vv > VL then neglect VL
= RT if vapour is ideal
= 8.314 x 353.2; T = 273 + 80.2 = 353.2K
= 2936.4 J mol-1.
E= q – w First law
= 30810.0 – 2936.4
= 27873.6 J
H = qP = 30810 J mol-1.
 Example
Calculate the work done when 18.0 g of liquid water is vaporized at 100oC
against a constant external pressure of 1.00 atm, given that:
R= 0.0820 liter atm mole-1deg-1 = 1.99 cal mole-1deg-1
At 100oC density of H2O (l) = 1.00 g cm-3 and that of water vapor is 0.58824
g/liter.The molecular weight of water = 18.0 g mole-1.
m
D 
V
w  PdV  P(V  V ) m
f i V 
D

VF = V (vapour) = 18/0.58824 = 30.5997 L
Vi = V(L) = 18/1 = 18 cm3 = 0.018 L
w  PdV  1*(30.6  0.018)  30.582L.atm
 (30.582 / 0.082)*1.99  742.17Cal
Example
Calculate ΔE in joule for a system that performs 213 kJ of work on its
surroundings and loses 79 kJ of heat
E = q- w

= -79-213 =-292 kJ

the system absorbs heat from the surroundings, q is positive.
f work is done by the system against the surroundings,(expansion) PdV is positive.
Work done on the system (compressing a gas) is negative.
Example
Calculate the change in the internal energy of the system for a process i
which the system absorbs 140 J of heat from the surroundings and does
85 J of work on the surroundings.

E = q- w

=140-85 =55 J