Energy
Chemical reactions proceed if the products of the reaction
have lower free energies than do the reactants. What does the
term free energy mean? Free Energy is defined in the field of
thermodynamics. Thermodynamics is simply the formulation of some
rules and definitions that can be extended to non-ideal states.
Thermodynamics
defines two terms:
Enthalpy
( H )
2. Entropy
( S )
It also relates these terms to each other in the definition of
free energy. In this course we will greatly simplify. For a
biological system define enthalpy ( H ) as the internal energy of
a system. More simply enthalpy is equal to the heat of a system.
Define entropy
(S) as:
S = klnW
Entropy is
equal to a constant times the natural log of the number of ways
something can be arranged. This equates to a measurement of the
randomness of a system. The entropy of the universe is
increasing. Any localized decrease in entropy must be balanced by
a greater increase in the total entropy of the universe.
Define Gibbís
Free Energy:
G = H - TS
DG = DH - TDS
A careful analysis of the meaning of the terms utilized to define
G yields the fact that changes in G may be equated to the
useful work that may be obtained from a system. When proper
substitutions are made:
D G = - RT
ln Keq
If a mole of A plus a mole of B equals 0.999 moles of C at
equilibrium, Then:
A + B = C
Keq = 9.99 x 105
If the reaction occurred at 25 C = 298 K, then:
D G =
-1.987 x 298 x lnKeq
ln 9.99 x 105 = 13.8
D G = -1.987 ( 298 ) (
13.8 )
D G = 8.2 Kcal/mole
Reaction Rates
Define Q10 = Ratio of reaction rates for a
10 C change
The normal range of Q10 is usually from 2 to 5.
| Temperature | Q10 |
|||
| 2.0 | 2.5 | 3.0 | 4.0 | |
Relative Reaction Rate (0 C = 1) |
||||
| 0 | 1 | 1 | 1 | 1 |
| 10 | 2 | 2.5 | 3 | 4 |
| 20 | 4 | 6 | 9 | 16 |
| 30 | 8 | 16 | 27 | 64 |
| 40 | 32 | 98 | 243 | 1020 |
| 50 | 128 | 610 | 2190 | 16,400 |
| 100 | 1,020 | 9,540 | 59,000 | 1,050,000 |
k = Ae-Ea/RT
A plot of ln K versus 
yields:
If the equation is evaluated between k1 and k2 at T1 and T2:
Can solve for Ea. In practice, any property proportional to k
can be used. Chemical reactions occur when collisions between
molecules of high enough energy occur.
k = PZe-Ea/RT
Where:
P = probability of a reaction occurring
Z = number of collisions per unit volume
e-Ea/RT = fraction of total number of molecules with an energy of
Ea or greater.
Assume that P is independent of temperature and that Z is
directly proportional to temperature, then:
For a 10 C change, D Z = 3.7%. This can be ignored. Then:
Where:
n1 = number of molecules with an energy of Ea or greater
n = the total number of molecules
If Ea = 12,000 cal/mole and T = 27 C, Then:
If the temperature is increased to 37 C, Then:
The ratio of the two rates is
Thus for a reaction with an energy of activation of 12,500
cal/mole if the temperature is increased 10 C the rate of the
reaction will increase by 1.97 times or approximately double.
