NEET Chemistry Thermodynamics / रासायनिक उष्मागतिकी Notes - Free Energy and Work Function

Free Energy and Work Function

Gibb's free energy (G) is a state function and is a measure of maximum work done or useful work done from a reversible reaction at constant temperature and pressure.

      (1) Characteristics of free energy

(i) The free energy of a system is the enthalpy of the system minus the product of absolute temperature and entropy i.e., \[G=H-TS\]

(ii) Like other state functions E, H and S, it is also expressed as \[\Delta G\]. Also \[\Delta G=\Delta H-T\Delta {{S}_{system}}\]where \[\Delta S\] is entropy change for system only. This is Gibb's Helmholtz equation.

      (iii)    At equilibrium   \[\Delta G=0\]

      (iv) For a spontaneous process decrease in free energy is noticed i.e., \[\Delta G=-ve\].

(v) At absolute zero, \[T\Delta S\]is zero. Therefore if \[\Delta G\]is ? ve, \[\Delta H\]should be ? ve or only exothermic reactions proceed spontaneously at absolute zero.

      (vi) \[\Delta {{G}_{system}}=T\Delta {{S}_{universe}}\]

      (vii) The standard free energy change,  \[\Delta {{G}^{o}}=-2.303RT{{\log }_{10}}\,K,\] where K is equilibrium constant.

(a) Thus if \[K>1,\]then \[\Delta {{G}^{o}}=-ve\]thus reactions with equilibrium constant K>1 are thermodynamically spontaneous.

         (b) If K<1, then \[\Delta {{G}^{o}}=+ve\] and thus reactions with equilibrium constant K<1 are thermodynamically spontaneous in reverse direction.

(2) Criteria for spontaneity of reaction: For a spontaneous change \[\Delta G=-ve\] and therefore use of \[\Delta G=\Delta H-T\Delta S,\]provides the following conditions for a change to be spontaneous.