Saturday, August 30, 2014

Thermodynamics-Notes

                                          UNIT 6    THERMODYNAMICS

It is the branch of chemistry which deals with energy changes of macroscopic systems.
Thermodynamic  terms: SYSTEM:-It is that part of universe in which energy changes are made.
SURROUNDING:-The part of universe other than system is called surrounding.
Universe=System+surrounding   , Boundry is the wall which separates system and surrounding.
Types  of system:- 1.Open system:- In this system , there is an exchange of matter as well as energy between system and surroundings. E.g. Reactants in an open beaker.
2.Closed system:- In this system , there is an exchange of  energy but not matter  between system and surroundings. E.g. Reactants in a closed beaker.
3.Isolated system:- In this system , there is neither exchange of matter nor energy between system and surroundings. E.g. Tea in thermos flask.
State of system is the state of existence of  system which can be described in terms of state variables
State variables are those variables which describe the state of system. These are mainly macroscopic properties like P , T, V and amount of substance(n).
Internal  energy is the total amount of energycontained within a system, which is the sum of  chemical, electrical, mechanical and other types of energies. It can change when:  1. Heat passes into or out of the system.   2. Work is done on or by the system.   3. Matter enter or leaves the system.
Adiabatic process is that in which there is no transfer of heat between system and surrounding. So temperature of the system changes.
Isothermal process is that in which there is an exchange of energy with the surroundings. So temperature of the system changes.
We can change the state of system by  mechanical work or electrical work. In both of the cases, there is change in temperature(∆T) as well as internal energy(∆U). Which is given by  ∆T=T2-T1 , change in internal energy (∆U) = U2-U1 ,  also ∆U=q(heat absorbed by the system)
Sign conventions:-   Work done on the system= +w   ,  work done by the system= -w  ,  heat absorbed by the system= +q  , heat given out of system = -q
First law of thermodynamics:- Energy of an isolated system is always constant.  ∆U = q+w .      if w=0 , q=0 then ∆U =0 for an isolated system.

Derivation for mechanical work or pressure-volume work:-

Consider one mole of ideal gas filled in a cylinder fitted with frictionless piston and the work of compression is going on.
Vi = initial volume of gas.   Vf = final volume of gas.  Pex = external pressure.  P = Total pressure.  By the application of Pex , piston covers distance  l and volume changes from Vi to Vf. Then work done on the system is given by:
  W = force  X distance    OR   W = Pex .A X l as ( F= PA)& ( Axl = V) ,  W = Pex .(- ∆V) or  W = -P∆V
Here negative sign is used to make w +ve , as volume change will be –ve in compression work.
Reversible process is that process which proceeds infinitely slowely by a series of equilibrium states and even a  small change can reverse the process. (while irreversible process cannot be reversed back)
Various forms  of ∆U = q+w :-
1.     For  isothermal irreversible change:  q = -w = P∆V.                                                                         
2.     For  isothermal reversible change: q = -w = 2.303 nRT log Vf/Vi
3.     For adiabatic change; q=0 , ∆U =Wad
ENTHALPY( H) : If we consider that heat is absorbed by the system constant pressure (qp) then expansion work will be done by the system(-w) . so      ∆U = qp - p∆V
                                                       U2-U1 = qp –p (V2-V1)   on rearranging we get
                                                            Qp  =( U2+pV2) – (U1+pV1)  but  U+PV= H
                                                             Qp = H2 – H1  or   qp = ∆H
 so enthalpy change is heat absorbed at constant pressure. We can also write ∆H= ∆U+p∆V.   ∆H is negative for exothermic reactions and positive for endothermic reactions. At constant volume, ∆V=0, so the above equation becomes ∆H = ∆U = qv. Here qv is heat absorbed at constant volume.
Consider two gases with volume V1 and V2 , no. Of moles of gaseous reactants are n1 and n2.  So   pV1 = n1RT  and  pV2 = n2RT  then  p( V2-V1) = (n2-n1) RT    or we can conclude that        p∆V  =  ∆nRT  where ∆n= moles of gaseous products – moles of gaseous reactants
Hence the new equation becomes     ∆H = ∆U + ∆nRT
Extensive property is a property whose value depends on quantity of matter present in the system. E.g. mass, volume, internal energy, enthalpy and heat capacity.
Intensive property is a property which depends upon nature of matter and is independent of the quantity of matter. E.g. temperature, density, pressure.
Molar property is the value of extensive property of system for one mole of substance.
Specific heat capacity is the quantity of heat required to raise the temperature of unit mass of  substance by one degree Celsius.
Molar heat capacity is the heat capacity for one mole of substance.
We know that      Heat supplied ∞   change in temperature
                                             q    ∞  ∆T   or    q= C∆T  (C is heat capacity)
                                                                      q = cm ∆T (c=specific heat ,m=no. of moles)
Relationship between Cp and Cv
We know that  at constant temperature  qv = Cv∆T = ∆U
                At  constant pressure,  qp = Cp∆T = ∆H
For one mole of ideal gas,  ∆H = ∆U + P∆V  or   ∆H = ∆U + R∆T
                                                                        Cp∆T = Cv∆T + R∆T  or   Cp – Cv = R
Measurements of  ∆H and ∆U is on page 163 and 164 of NCERT
Reaction enthalpy is the enthalpy change accompanying a reaction.
rH = Total enthalpies of products – total enthalpies of reactants
Eg.   CH4 + 2O2 à CO2 + 2H2O
   ∆rH = [Hm(CO2) + 2Hm(H2O)]  -  [Hm(CH4) + 2Hm(O2)]
Note: do the definition of following enthalpies from NCERT
Enthalpy of fusion   H2O(s) à H2O(l)      ∆fus H = 6 kJ/mol
Standard enthalpy of vapourisation     H2O(l) à H2O(g)      ∆vap H0 = 40.79 kJ/mol
Standard enthalpy of sublimation       CO2(s) à CO2(g)     ∆sub H0 = 25.2 kJ/mol
Standard enthalpy of formation          H2 + 1/2O2 à H2O      ∆f H0 = -285.8 kJ/mol
Enthalpy of formation can be used to calculate enthalpy change for the reaction:
     CaCO3  à CaO + CO2 ,    ∆rH = [∆fH(CaO) + ∆fH(CO2)]  -  ∆fH(CaCO3)
                                                 = [-635.1 -393.5] – (-1206.9)  = 178.3 kj/mol  (endothermic)
Thermochemical equation is the balanced chemical equation along with the value of ∆rH.
Eg. C2H5OH + 3O2 à 2CO2 + 3H2O   ∆rH = -1367kJ/mol
Calculations for the heat of reaction:-     Fe2O3 + 3H2 à 2Fe + 3H2O
Given : ∆fH(H2O) = -283.83 kJ/mol , ∆fH(Fe2O3) =  -824.2 kJ/mol
 ∆rH = 3 [∆fH(H2O)] – [∆fH (Fe2O3)]
        = 3x -285.83  -  (-824.2) =  -33.3 kJ/mol
Hess’s law :- If a reaction takes place in several steps then its standard reaction enthalpy is the sum of standard enthalpies of all intermediate reactions, into which the overall reaction may be divided at the same temperature.
∆rH = ∆rH1 + ∆rH2 + ∆rH3   (if reaction is taking place in three steps)
ENTHALPIES
1.     Std. enthalpy of combustion C4H10 + 13/2O2 à 4CO2 + 5H2O  ∆cH0=  -2658kJ/mol
2.     Enthalpy of atomisation  CH4  à C + 4H   ∆aH0=  1665kJ/mol
3.     Bond enthalpy   a. For diatomic molecule   H2  à H + H         ∆H-H H= 435kJ/mol
b. For polyatomic molecules       H2àH + OH     ∆bH=  502kJ/mol
                                                 OH à O + H            ∆bH= 427kJ/mol
                                           ∆O-H H0=  ½ (∆bH) = ½ x 929 = 464.5 kJ/mol
Relation between standard reaction enthalpy and bond enthalpy:
rH0  = ∑Bond enthalpies of reactants - ∑Bond enthalpies of products
4.     Enthalpy of solution is the enthalpy change when one mole of substance dissolves in a specified amount of solvent.
                ∆sol H0
AB( s)                                 A+(aq) + B-(aq)
latticeH0
                                                            ∆hydH0
              A+(g) + B-(g)
                                                         So       ∆solH=     latticeH0   +  hydH0
5.     Lattice enthalpy is the enthalpy change which occurs when one mole of an ionic compound dissociates into its ions in gaseous state.
e.g. Na+Cl-   à Na+(g) + Cl-(g)           ∆latticeH= +788kJ/mol

We can calculate lattice enthalpy by Born – Haber cycle
                 Na(s)+1/2Cl2 (g                                   
 


 121KJ/mol      1/2 ∆bondH0
 Na(s)+1/2Cl2 (g             -348.6   ∆egH0
495.6                 ∆iH0
 Na(s)+1/2Cl2 (g           Na(s)+1/2Cl2 (g
108.4                ∆subH0
Na(s)+1/2Cl2 (g)                      ∆latticeH0
-411.2               ∆fH0



                       NaCl (s)
Applying Hess’s law here we get     ∆latticeH0 = 411.2 + 108.4 + 121+ 496 - 348.6 = 788 kJ
                 But     ∆solH=  ∆latticeH0 +  hydH = 788 – 784(from literature) = 4 kJ/mol
Spontaneity means having the potential to proceed without getting the assistance of external agency. The deriving forces for spontaneous process are:
1.     Decrease in enthalpy    2.  Increase in entropy.
So we can say that all exothermic processes are spontaneous becoz they have tendency to get minimum energy. But here the question arises on the spontaneity of endothermic processes like  C(s) + 2S(l) à CS2(l)          ∆rH0 = +128.5kJ/mol
Now the answer can be increase in randomness. Heat added to the system at lower temperature causes greater randomness than heat added at higher temp.
So     ∆S=qrev/T     and          ∆Stotal  =  ∆Ssystem +  ∆Ssur
When the system is in equilibrium, entropy is maximum and ∆S=0. So we can say that entropy of spontaneous process increases till it reaches maximum and at equilibrium, entropy change is zero. So ∆S of reversible process is ∆Ssys=qsys.rev /T
Both for reversible and irreversible processes ∆U=0 but ∆Stotal is not 0 for irreversible system.
Problem: For 4Fe(s) + 3O2(g) à 2Fe2O3(s)      ∆S= -549.4J/K/mol
Why is the reaction spontaneous with –ve entropy. Given ∆rH=-1648x103 J/mol
Ans. If we consider that heat absorbed by surroundings is -∆rH then
 ∆Ssur= -∆rH/T = -(-1648x103)/298 = 5530J/K/mol   But     ∆Stotal  =  ∆Ssystem +  ∆Ssur     so     ∆S=5530-549.4 = 4980.6 J/K/mol       and reaction is spontaneous.
GIBBS ENERGY AND SPONTANEITY :-  Gibbs function , an extensive property or a state function can be written as   G=H-TS    or  ∆G = ∆H - T∆S (at constant temp.)
In thermal equilibrium, temp. of system and surrounding is equal. Increase in enthalpy of surrounding is equal to decrease in enthalpy of system.
So    ∆Ssur = ∆Hsur/T  = - ∆Hsys/T
   ∆Stotal  =  ∆Ssystem +  ∆Ssur    
∆Stotal  =  ∆Ssystem -  ∆Hsys/T   on rearranging, we get  T∆Stot = T∆Ssys - ∆Hsys
For a spontaneous process ∆Stot >0  or  T∆Ssys - ∆Hsys>0  ,  -(∆H-T∆S)>0  ,  -∆G>0
Or  ∆G<0 for a spontaneous process.
∆G & EQUILIBRIUM:-  ∆G allows us to  i) predict the spontaneity of reaction    ii)predict the useful work extracted from the system.
At equilibrium, ∆G=0 . standard free energy is related to equilibrium constant(K)  as
   ∆rG0 = -RT ln K  , ∆rG0 = -2.303 RT log K  or    ∆rH0 - T∆S0 = -2.303 RT log K

For endothermic reaction: ∆H0 large +ve ,  K<1For exothermic reaction: ∆H0 large -ve   ,  K>1

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