Free energy     61


        in solids. However, because most chemical and biochemical systems  take  place  at
        constant  pressure, the Gibbs free energy is by far the more commonly encountered
        property.


                            General properties of the free energies

        Because they are wholly derived from state functions, it follows that both the Gibbs and
        Helmholtz free energies are also state functions. Both of the free energies do not have
        measurable absolute values, and calculations involving free energy  changes  may  be
        manipulated in the same manner as, for example, enthalpy changes. Hess’s law may be
        applied to free energies, and it is similarly useful to define free energies of formation for
        substances.
           A most important property of the free energy is that it not only provides an indication
        of the spontaneity of a process but it also represents the maximum amount of work, other
        than volume expansion work, which may be obtained from a process. This differs from
        the heat which may be obtained from a process, because the total entropy change must be
        greater than zero. For example, in the case of a reaction for which ∆S system is negative,
        some heat must be lost to the surroundings and contribute to ∆S surroundings in order that
        ∆S totalis greater than zero. The value of the heat which is then unavailable for conversion
        into work is given by T∆S system.


                                Free energy and spontaneity

        For a  spontaneous process,  ∆S total is positive and  ∆G is therefore  negative.  The
        relationship ∆G=∆H−T∆S system allows prediction of the conditions under which a reaction
        is spontaneous. As T must be positive, the relationships may be summarized in Table 1.
                        Table 1. Free energy and the spontaneity of
                        reactions

        ∆H         ∆S         Spontaneous?           Spontaneity favored by
        Negative   Positive   Under all conditions   All conditions
        Negative   Negative   If |T∆S|<|∆H|          Low temperatures
        Positive   Positive   If |T∆S|>|∆H|          High temperatures
        Positive   Negative   Never                  No conditions

        Temperature has a major impact on the spontaneity  of  some reactions as indicated in
        Table 1. For a reaction where ∆H<0 and ∆S<0, |T∆S| will be less than |∆H| provided that
        T is small, and such a reaction will be spontaneous at lower temperatures. Conversely,
        when ∆H>0 and ∆S>0, |T∆S| will be greater than |∆H| provided that T is large, and such a
        reaction will become spontaneous at higher temperatures. In both cases, the temperature
        at which the reaction becomes spontaneous (when ∆G=0) is simply given by T=∆H/∆S.