Gaseous State : Vander Waal Gas Equation

 

Real and ideal gases

(1)     Gases which obey gas laws or ideal gas equation (PV = nRT) at all temperatures and pressures are called ideal or perfect gases. Almost all gases deviate from the ideal behaviour i.e., no gas is perfect and the concept of perfect gas is only theoretical.

(2)     Gases tend to show ideal behaviour more and more as the temperature rises above the boiling point of their liquefied forms and the pressure is lowered. Such gases are known as real or non ideal gases. Thus, a “real gas is that which obeys the gas laws under low pressure or high  temperature”.

(3)     The deviations can be displayed, by plotting the P-V isotherms of real gas and ideal gas.

(4)     It is difficult to determine quantitatively the deviation of a real gas from ideal gas behaviour from the P-V isotherm curve as shown above. Compressibility factor Z defined by the equation,

          PV = ZnRT or Z = PV/nRT = PVm/RT

is more suitable for a quantitative description of the deviation from ideal gas behaviour.

(5)     Greater is the departure of Z from unity, more is the deviation from ideal behaviour. Thus, when

(i)      Z = 1, the gas is ideal at all temperatures and pressures. In case of N2, the value of Z is close to 1 at 50oC. This temperature at which a real gas exhibits ideal behaviour, for considerable range of pressure, is known as Boyle’s temperature or Boyle’s point (TB).

(ii)     Z > 1, the gas is less compressible than expected from ideal behaviour and shows positive deviation, usual at high P i.e. PV > RT.

(iii)    Z > 1, the gas is more compressible than expected from ideal behaviour and shows negative deviation, usually at low P i.e. PV < RT.

(iv)    Z > 1 for H2 and He at all pressure i.e., always shows positive deviation.

(v)     The most easily liquefiable and highly soluble gases (NH3, SO2) show larger deviations from ideal behaviour i.e. Z << 1.

(vi)    Some gases like CO2 show both negative and positive deviation.

(6)     Causes of deviations of real gases from ideal behaviour : The ideal gas laws can be derived from the kinetic theory of gases which is based on the following two important assumptions,

(i)      The volume occupied by the molecules is negligible in comparison to the total volume of gas.

(ii)     The molecules exert no forces of attraction upon one another. It is because neither of these assumptions can be regarded as applicable to real gases that the latter show departure from the ideal behaviour.

 

Vander Waal’s equation

(1)      To rectify the errors caused by ignoring the intermolecular forces of attraction and the volume occupied by molecules, Vander Waal (in 1873) modified the ideal gas equation by introducing two corrections,

            (i)      Volume correction     

            (ii)     Pressure correction

(2)      Vander Waal’s equation is obeyed by the real gases over wide range of temperatures and pressures, hence it is called equation of state for the real gases.

(3)     The Vander Waal’s equation for n moles of the gas is,

 \underset { Pressure\quad correction\quad for\quad molecular\quad attraction }{ \left( P+\frac { { n }^{ 2 }a }{ { V }^{ 2 } } \right) }         \underset { Volume\quad correction\quad for\quad finite\quad size\quad of\quad molecules }{ [V-nb] }

a and b are Vander Waal’s constants whose values depend on the nature of the gas. Normally for a gas a >> b.

(i)      Constant a : It is a indirect measure of magnitude of attractive forces between the molecules. Greater is the value of a, more easily the gas can be liquefied. Thus the easily liquefiable gases (like SO2 > NH3 > H2S > CO2) have high values than the permanent gases (like N2 > O2 > H2 > He).

Units of ‘a‘ are : atm. L2 mol–2 or atm. m6 mol–2 or Nm4 mol–2 (S.I. unit).

(ii)     Constant b : Also called co-volume or excluded volume,

b = 4N0 \left( =\frac { 4 }{ 3 } \pi { r }^{ 3 } \right)

It’s value gives an idea about the effective size of gas molecules. Greater is the value of b, larger is the size and smaller is the compressible volume. As b is the effective volume of the gas molecules, the constant value of b for any gas over a wide range of temperature and pressure indicates that the gas molecules are incompressible.

            Units of ‘b‘ are : L mol–1 or m3 mol–1 (S.I. unit)

(iii)    Vander Waal’s constant for some gases are,

Name of gas a b
atm litre2 mol–2 Nm4 mol–2 litre mol–1 m3 mol–1
Hydrogen 0.245 0.0266 0.0266 0.0266
Oxygen 1.360 0.1378 0.0318 0.0318
Nitrogen 1.390 0.1408 0.039 0.0391
Chlorine 6.493 0.6577 0.0562 0.0562
Carbon dioxide 3.590 0.3637 0.0428 0.0428
Ammonia 4.170 0.4210 0.0371 0.0371
Sulphurdioxide 6.170 0.678 0.0564 0.0564
Methane 2.253 0.0428
           

(iv)    The two Vander Waal’s constants and Boyle’s temperature (TB) are related as, TB =  \frac { a }{ bR }

 

(4)     Vander Waal’s equation at different temperature and pressures:

(i)      When pressure is extremely low : For one mole of gas,

(P +  \left\frac { a }{ { V }^{ 2 } } \right)   (V-b) = RT  or  PV = RT –  \frac { a }{ { V } } + Pb +  \frac { ab }{ { V }^{ 2 } }

(ii)     When pressure is extremely high : For one mole of gas,

PV = RT + Pb ;  \frac { PV }{ RT } = 1 +  \frac { Pb }{ RT }   or  Z = 1 +  \frac { Pb }{ RT }

where Z is compressibility factor.

(iii)    When temperature is extremely high : For one mole of gas,

PV = RT.

(iv)    When pressure is low : For one mole of gas,

(P +  \left\frac { a }{ { V }^{ 2 } } \right)   (V-b) = RT  or  PV = RT + Pb –  \frac { a }{ { V } } + \frac { ab }{ { V }^{ 2 } }

 \frac { PV }{ RT } = 1 –  \frac { a }{ VRT }   or  Z = 1 –  \frac { a }{ VRT }  

(v)      For hydrogen : Molecular mass of hydrogen is small hence value of ‘a‘ will be small owing to smaller intermolecular force. Thus the terms \frac { a }{ V } and    \frac { ab }{ V^{ 2 } }   may be ignored. Then Vander Waal’s equation becomes, 

PV = RT + Pb or   \frac { PV }{ RT } = 1 +  \frac { Pb }{ RT }   or  Z= 1 +  \frac { Pb }{ RT }

In case of hydrogen, compressibility factor is always greater than one.

(5)     Merits of Vander Waal’s equation :

(i)      The Vander Waal’s equation holds good for real gases upto moderately high pressures.

(ii)     The equation represents the trend of the isotherms representing the variation of PV with P for various gases.

(iii)    From the Vander Waal’s equation it is possible to obtain expressions of Boyle’s temperature, critical constants and inversion temperature in terms of the Vander Waal’s constants ‘a‘ and ‘b‘.

(iv)    Vander Waal’s equation is useful in obtaining a ‘reduced equation of state’ which being a general equation of state has the advantage that a single curve can be obtained for all gases when the equation if graphically represented by plotting the variables.

 

(6)     Limitations of Vander Waal’s equation :

(i)      This equation shows appreciable deviations at too low temperatures or too high pressures.

(ii)     The values of Vander Waal’s constants a and b do not remain constant over the entire ranges of T and P, hence this equation is valid only over specific range of T and P.

 

(7)     Other equations of state : In addition to Vander Waal’s equation, there are also equations of state which have been used to explain real behavior of gases are,

(i)      Clausius equation :  [P + \frac { a }{ T(V+c)^{ 2 } } ]  (V-b) = RT. Here ‘c‘ is another constant besides a, b and R.

(ii)     Berthelot equation : (P + \frac { a }{ TV^{ 2 } } )  (V-b) = RT.

(iii)    Wohl equation : P = \frac { RT }{ (V-b) }  \frac { a }{ V(V-b) } +  \frac { c }{ V^{ 2 } }

(iv)    Dieterici equation : P =  \frac { RT }{ V-b } { e }^{ -a/RTV }\quad . The expression is derived on the basis of the concept that molecules near the wall will have higher potential energy than those in the bulk.

(v)     Kammerlingh Onnes equation : It is the most general or satisfactory expression as equation expresses PV as a power series of P at a given temperature.

                     PV = A + BP + CP2 + DP3 + …..

Here coefficients A, B, C etc. are known as first, second and third etc. virial coefficients.

            (a)     Virial coefficients are different for different gases.

            (b)     At very low pressure, first virial coefficient, A = RT.

            (c)      At high pressure, other virial coefficients also become important and must be considered.

 

The critical state

(1)     A state for every substance at which the vapour and liquid states are indistinguishable is known as critical state. It is defined by critical temperature and critical pressure.

(2)     Critical temperature (Tc) of a gas is that temperature above which the gas cannot be liquified however large pressure is applied. It is given by, Tc =  \frac { 8 }{ 27Rb }

(3)     Critical pressure (Pc) is the minimum pressure which must be applied to a gas to liquify it at its critical temperature. It is given by, Pc =  \frac { 8 }{ 27b^{ 2 } }

(4)     Critical volume (Vc) is the volume occupied by one mole of the substance at its critical temperature and critical pressure. It is given by, Vc = 3b

(5)     Critical compressibility factor (Zc) is given by, Zc =  \frac { { P }_{ c }V_{ c } }{ RT_{ c } } =\frac { 3 }{ 8 } = 0.375

A gas behaves as a Vander Waal’s gas if its critical compressibility factor (Zc) is equal to 0.375.          

Note :    A substance in the gaseous state below Tc is called vapour and above Tc is called gas.

 

The principle of corresponding states

(1)     In 1881, Vander Waal’s demonstrated that if the pressure, volume and temperature of a gas are expressed in terms of its Pc, Vc and Tc, then an important generalization called the principle of corresponding states would be obtained.

(2)     According to this principle, “If two substances are at the same reduced temperature (θ) and pressure (π) they must have the same reduced volume (∅),” i.e.  \left( \pi +\frac { 3 }{ \phi ^{ 2 } } \right) (3\phi -1) = 80

            where, ∅ = V/Vc  or  V = ∅Vc  ;  π = P/Pc  or  P = πP ;  θ = T/T or  T = θTc

This equation is also called Vander Waal’s reduced equation of state. This equation is applicable to all substances (liquid or gaseous) irrespective of their nature, because it is not involving neither of the characteristic constants.

(3)     This principle has a great significance in the study of the relationship between physical properties and chemical constitution of various liquids.